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Home My WebLink AboutDRC-2020-016546 - 0901a06880d42435Energy Fuels Resources (USA) Inc. 225 Union Blvd. Suite 600 Lakewood, CO, US, 80228 303 974 2140 www.energyfuels.com NERGVFUELS August 14, 2020 Sent VIA EXPEDITED DELIVERY Mr. Ty L. Howard Director Division of Waste Management and Radiation Control Utah Department of Environmental Quality 195 North 1950 West P.O. Box 144880 Salt Lake City, UT 84114-4820 Div of Waste Management and Radiation Control AUG 1 9 2020 17P-c -2020-O 154-0, Re: Transmittal of 2nd Quarter 2020 Nitrate Monitoring Report Stipulation and Consent Order Docket Number UGW12-04 White Mesa Uranium Mill Dear Mr. Howard: Enclosed are two copies of the White Mesa Uranium Mill Nitrate Monitoring Report for the 2nd Quarter of 2020 as required by the Stipulation and Consent Order Docket Number UGW12-04, as well as two CDs each containing a word searchable electronic copy of the report. If you should have any questions regarding this report please contact me. Yours very truly, ra '11 44 ENERGY FUELS RESOURCES (USA) INC. Kathy Weinel Quality Assurance Manager cc: David Frydenlund Logan Shumway Terry Slade Scott Bakken Paul Goranson ~ ENERGY FUEL S August 14, 2020 Sent VIA EXPEDITED DELIVERY Mr. Ty L. Howard Director Di vision of Waste Management and Radiation Control Utah Department of Environmental Quality 195 North 1950 West P.O. Box 144880 Salt Lake City, UT 84114-4820 Energy Fuels Resources (USA) Inc. 225 Union Blvd. Suite 600 Lakewood, CO, US, 80228 303 974 2140 www .energyfuel. .com Re: Transmittal of 2nd Quarter 2020 Nitrate Monitoring Report Stipulation and Consent Order Docket Number UGW12-04 White Mesa Uranium Mill Dear Mr. Howard: Enclosed are two copies of the White Mesa Uranium Mill Nitrate Monitoring Report for the 2nd Quarter of 2020 as required by the Stipulation and Consent Order Docket Number UGW12-04, as well as two CDs each containing a word searchable electronic copy of the report. If you should have any questions regarding this report please contact me. Yours very truly, f(~£f~ ENERGY FUELS RESOURCES (USA) INC. Kathy Weinel Quality Assurance Manager cc: David Frydenlund Logan Shumway Terry Slade Scott Bakken Paul Goranson White Mesa Uranium Mill Nitrate Monitoring Report State of Utah Stipulated Consent Agreement, December 2014 Docket No. UGW12-04 2nd Quarter (April through June) 2020 Prepared by: Energy Fuels Resources (USA) Inc. 225 Union Boulevard, Suite 600 Lakewood, CO 80228 August 14, 2020 TABLE OF CONTENTS 1.0 INTRODUCTION ................................................................................................. 1 2.0 GROUNDWATER NITRATE MONITORING ................................................ I 2.1 Samples and Measurements Taken During the Quarter ..................................... 1 2.1.1 Nitrate Monitoring ...................................................................................... 1 2.1.2 Parameters Analyzed .................................................................................. 2 2.1.3 Groundwater Head and Level Monitoring .................................................. 3 2.2 Sampling Methodology and Equipment and Decontamination Procedures ....... 3 2.2.1 Well Purging, Sampling and Depth to Groundwater .................................. 3 2.2.2 Piezometer Sampling .................................................................................. 4 2.3 Field Data ............................................................................................................ 5 2.4 Depth to Groundwater Data and Water Table Contour Map .............................. 5 2.5 Laboratory Results .............................................................................................. 5 2. 5 .1 Copy of Laboratory Results ........................................................................ 5 2.5.2 Regulatory Framework ............................................................................... 5 3.0 QUALITY ASSURANCE AND DATA VALIDATION ................................... 5 3.1 Field QC Samples ............................................................................................... 6 3.2 Adherence to Mill Sampling SOPs ..................................................................... 6 3.3 Analyte Completeness Review ........................................................................... 6 3.4 Data Validation ................................................................................................... 6 3.4.1 Field Data QA/QC Evaluation .................................................................... 7 3.4.2 Holding Time Evaluation ............................................................................ 8 3.4.3 Analytical Method Checklist ...................................................................... 8 3.4.4 Reporting Limit Evaluation ........................................................................ 8 3.4.5 QA/QC Evaluation for Sample Duplicates ................................................. 8 3.4.6 Other Laboratory QA/QC ........................................................................... 8 3.4.7 Receipt Temperature Evaluation ................................................................. 9 3.4.8 Rinsate Check ............................................................................................. 9 4.0 INTERPRETATION OF DATA ....................................................................... 10 4.1 Interpretation of Groundwater Levels, Gradients and Flow Directions ........... 10 4.1.1 Current Site Groundwater Contour Map ................................................... 10 4.1.2 Comparison of Current Groundwater Contour Map to Groundwater Contour Map for Previous Quarter .................................................................................. 14 4.1.4 Depth to Groundwater Measured and Groundwater Elevation ................. 16 4.2 Effectiveness of Hydraulic Containment and Capture ...................................... 16 4.2.1 Hydraulic Containment and Control.. ....................................................... 16 4.2.2 Current Nitrate and Chloride Isoconcentration Maps ............................... 20 4.2.3 Comparison of Areal Extent ............................................................................ 20 4.2.4 Nitrate and Chloride Concentration Trend Data and Graphs .................... 21 4.2.5 Interpretation of Analytical Data .............................................................. 21 4.3 Estimation of Pumped Nitrate Mass and Residual Nitrate Mass within the Plume ·························································································································· 23 5.0 LONG TERM PUMP TEST AT TWN-02, TW4-22, TW4-24, and TW4-25 OPERA TIO NS REPORT .................................................................................. 25 5 .1 Introduction ....................................................................................................... 25 5.2 Pumping Well Data Collection ......................................................................... 25 l 5.3 Water Level Measurements .............................................................................. 26 5.4 Pumping Rates and Volumes ............................................................................ 26 5.4.1 TW4-19 ............................................................................................................ 27 6.0 6.1 7.0 8.0 9.0 Table 1 Table 2 Table 3 Table 4 Table 5 Table 6 Table 7 Table 8 Table 9 CORRECTIVE ACTION REPORT ................................................................. 27 Assessment of Previous Quarter's Corrective Actions ..................................... 27 CONCLUSIONS AND RECOMMENDATIONS ............................................ 27 ELECTRONIC DATA FILES AND FORMAT .............................................. 31 SIGNATURE AND CERTIFICATION ........................................................... 32 LIST OF TABLES Summary of Well Sampling and Constituents for the Period Nitrate Mass Removal Per Well Per Quarter Nitrate Well Pumping Rates and Volumes Quarterly Calculation of Nitrate Mass Removed and Total Volume of Water Pumped Nitrate Data over Time for MW-30, MW-31, MW-5, and MW-11 Slug Test Results Pre-Pumping Saturated Thickness Pre-Pumping Hydraulic Gradients and Flow Calculations Recalculated Background Flow 11 INDEX OF TABS Tab A Site Plan and Perched Well Locations White Mesa Site Tab B Order of Sampling and Field Data Worksheets Tab C Kriged Current Quarter Groundwater Contour Map and Weekly, Monthly and Quarterly Depth to Water Data Tab D Kriged Previous Quarter Groundwater Contour Map Tab E Hydrographs of Groundwater Elevations over Time for Nitrate Monitoring Wells Tab F Depths to Groundwater and Elevations over Time for Nitrate Monitoring Wells Tab G Laboratory Analytical Reports Tab H Quality Assurance and Data Validation Tables H-1 Field Data QA/QC Evaluation H-2 Holding Time Evaluation H-3 Analytical Method Check H-4 Reporting Limit Evaluation H-5 QA/QC Evaluation for Sample Duplicates H-6 QC Control limits for Analysis and Blanks H-7 Receipt Temperature Evaluation H-8 Rinsate Evaluation Tab I Kriged Current Quarter Nitrate and Chloride lsoconcentration Maps Tab J Analyte Concentration Data Over Time Tab K Nitrate and Chloride Concentration Trend Graphs Tab L CSV Transmittal Letter Tab M Residual Mass Estimate Analysis Figure iii ACRONYM LIST AWAL CA CAP CIR DIFB DWMRC DRC EFRI ft amsl GWDP LCS MS MSD QA QAP QC RPD sco SOPs UDEQ voe American West Analytical Laboratory Consent Agreement Corrective Action Plan Contamination Investigation Report Deionized Field Blanks Utah Di vision of Waste Management and Radiation Control Utah Division of Radiation Control Energy Fuels Resources (USA) Inc. feet above mean sea level Groundwater Discharge Permit Laboratory Control Spike Matrix Spike Matrix Spike Duplicate Quality Assurance Groundwater Monitoring Quality Assurance Plan Quality Control Relative Percent Difference Stipulated Consent Order Standard Operating Procedures Utah Department of Environmental Quality Volatile Organic Compound iv 1.0 INTRODUCTION The Utah Department of Environmental Quality ("UDEQ") Division of Waste Management and Radiation Control ("DWMRC") noted in a Request dated September 30, 2008 (the "Request"), for a Voluntary Plan and Schedule to Investigate and Remediate Nitrate Contamination at the White Mesa Uranium Mill (the "Mill") (the "Plan"), that nitrate levels have exceeded the State water quality standard of 10 mg/L in certain monitoring wells. As a result of the Request, Energy Fuels Resources (USA) Inc. ("EFRI") entered into a Stipulated Consent Agreement with the Utah Water Quality Board in January 2009 which directed the preparation of a Nitrate Contamination Investigation Report ("CIR"). A subsequent letter dated December 1, 2009, among other things, recommended that EFRI also address elevated chloride concentrations in the CIR. The Stipulated Consent Agreement was amended in August 2011. Under the amended Consent Agreement ("CA"), EFRI submitted a Corrective Action Plan ("CAP"), pursuant to the requirements of the Utah Groundwater Quality Protection Rules [UAC R317-6-6.15(C -E)] on November 29, 2011 and revised versions of the CAP on February 27, 2012 and May 7, 2012. On December 12, 2012, DWMRC signed the Stipulation and Consent Order ("SCO"), Docket Number UGW12-04, which approved the EFRI CAP, dated May 7, 2012. The SCO ordered EFRI to fully implement all elements of the May 7, 2012 CAP. Based on the schedule included in the CAP and as delineated and approved by the SCO, the activities associated with the implementation of the CAP began in January 2013. The reporting requirements specified in the CAP and SCO are included in this quarterly nitrate report. This is the Quarterly Nitrate Monitoring Report, as required under the SCO, State of Utah Docket No. UGW12-04 for the second quarter of 2020. This report meets the requirements of the SCO, State of UDEQ Docket No. UGW12-04 and is the document which covers nitrate corrective action and monitoring activities during the second quarter of 2020. 2.0 GROUNDWATER NITRATE MONITORING 2.1 Samples and Measurements Taken During the Quarter A map showing the location of all groundwater monitoring wells, piezometers, existing wells, temporary chloroform contaminant investigation wells and temporary nitrate investigation wells is attached under Tab A. Nitrate samples and measurements taken during this reporting period are discussed in the remainder of this section. 2.1.1 Nitrate Monitoring Quarterly sampling for nitrate monitoring parameters was performed in the following wells: TWN-1 TWN-2 TWN-3 TWN-4 TWN-7 TWN-18 TW4-22* TW4-24* TW4-25* Piezometer 1 Piezometer 2 Piezometer 3A ** 1 As discussed in Section 2.1.2 the analytical constituents required by the CAP are inorganic chloride and nitrate+nitrite as N (referred to as nitrate in this document) * Wells TW4-22, TW4-24, TW4-25 are chloroform investigation wells (wells installed and sampled primarily for the chloroform investigation) and are sampled as part of the chloroform program. The analytical suite for these three wells includes nitrate, chloride and a select list of Volatile Organic Compounds ("VOCs") as specified in the chloroform program. These three wells are included here because they are being pumped as part of the remediation of the nitrate contamination as required by the SCO and the CAP. The nitrate and chloride data are included in this report as well as in the chloroform program quarterly report. The VOC data for these three wells will be reported in the chloroform quarterly monitoring report only. ** Piezometer 3 was abandoned and replaced with Piezometer 3A in March 2016. The December 12, 2012 SCO approved the CAP, which specified the cessation of sampling in TWN-5, TWN-6, TWN-8, TWN-9, TWN-10, TWN-11, TWN-12, TWN-13, TWN-14, TWN-15, TWN-16, TWN-17, and TWN-19. The CAP and SCO also approved the abandonment of TWN- 5, TWN-8, TWN-9, TWN-10, TWN-11, TWN-12, TWN-13, TWN-15, and TWN-17 within 1 year of the SCO approval. These wells were abandoned in accordance with the DWMRC- approved Well Abandonment Procedure on July 31, 2013. Wells TWN-6, TWN-14, TWN-16, and TWN-19 have been maintained for depth to groundwater monitoring only, as noted in the CAP. Table 1 provides an overview of all locations sampled during the current period, along with the date samples were collected from each location, and the date(s) upon which analytical data were received from the contract laboratory. Table 1 also identifies rinsate samples collected, as well as sample numbers associated with any required duplicates. As indicated in Table 1, nitrate monitoring was performed in the nitrate monitoring wells, chloroform wells TW4-22, TW4-24, TW4-25 and Piezometers 1, 2, and 3A. Analytical data for all of the above-listed wells, and the piezometers, are included in Tab G. Nitrate and chloride are also monitored in all of the Mill's groundwater monitoring wells and chloroform investigation wells. Data from those wells for this quarter are incorporated in certain maps and figures in this report but are discussed in their respective programmatic reports. 2.1.2 Parameters Analyzed Locations sampled during this reporting period were analyzed for the following constituents: · • Inorganic Chloride • Nitrate plus Nitrite as Nitrogen (referred to herein as nitrate) Use of analytical methods consistent with the requirements found in the White Mesa Mill Groundwater Quality Assurance Plan, ("QAP") Revision 7.6, dated August 22, 2019 was confirmed for all analytes, as discussed later in this report. 2 2.1.3 Groundwater Head and Level Monitoring Depth to groundwater was measured in the following wells and/or piezometers, pursuant to Part I.E.3 of the Groundwater Discharge Permit ("GWDP"): • The quarterly groundwater compliance monitoring wells • Existing well MW-4 and all of the temporary chloroform investigation wells • Piezometers -P-1, P-2, P-3, P-4 and P-5 • MW-20, MW-22, and MW-34 • The DR piezometers that were installed during the Southwest Hydrogeologic Investigation • Nitrate wells TWN-1, TWN-2, TWN-3, TWN-4, TWN-6, TWN-7, TWN-14, TWN-16, TWN-18 and TWN-19 In addition to the above, depth to water measurements are routinely observed in conjunction with sampling events for all wells sampled during quarterly and accelerated efforts, regardless of the sampling purpose. All well levels used for groundwater contour mapping were measured and recorded within 5 calendar days of each other as indicated by the measurement dates in the summary sheet under Tab C. Field data sheets for groundwater measurements are also provided in Tab C. Weekly and monthly depth to groundwater measurements were taken in the chloroform pumping wells MW-4, MW-26, TW4-1, TW4-2, TW4-11, TW4-19, TW4-20, TW4-4, TW4-21, TW4-37, TW4-39, TW4-40, TW4-41, and the nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2. In addition, monthly water level measurements were taken in non-pumping wells MW-27, MW- 30, MW-31, TWN-1, TWN-3, TWN-4, TWN-7, and TWN-18 as required by the CAP. 2.2 Sampling Methodology and Equipment and Decontamination Procedures The QAP provides a detailed presentation of procedures utilized for groundwater sampling activities under the GWDP. The sampling methodology, equipment and decontamination procedures that were performed for the nitrate contaminant investigation, as summarized below, are consistent with the QAP. 2.2.1 Well Purging, Sampling and Depth to Groundwater A list of the wells in order of increasing nitrate contamination is generated quarterly. The order for purging is thus established. The list is included with the Field Data Worksheets under Tab B. Mill personnel start purging with all the nondetect wells and then move to the wells with detectable nitrate concentrations, progressing from the wells having the lowest nitrate contamination to wells with the highest nitrate contamination. 3 Before leaving the Mill office, the pump and hose are decontaminated using the cleaning agents described in Attachment 2-2 of the QAP. Rinsate blanks are collected at a frequency of one rinsate per 20 field samples. Purging is completed to remove stagnant water from the casing and to assure that representative samples of formation water are collected for analysis. There are three purging strategies specified in the QAP that are used to remove stagnant water from the casing during groundwater sampling at the Mill. The three strategies are as follows: 1. Purging three well casing volumes with a single measurement of field parameters 2. Purging two casing volumes with stable field parameters (within 10% Relative Percent Difference ["RPD"]) 3. Purging a well to dryness and stability (within 10% RPD) of a limited list of field parameters after recovery. Mill personnel proceed to the first well, which is the well with the lowest concentration (i.e. non- detect) of nitrate based on the previous quarter's sampling results. Well depth measurements are taken and the one casing volume is calculated. The purging strategy that will be used for the well is determined at this time based on the depth to water measurement and the previous production of the well. The Grundfos pump (a 6 to 10 gallon per minute [gpm] pump) is then lowered to the appropriate depth in the well and purging is started. At the first well, the purge rate is measured for the purging event by using a calibrated 5 gallon bucket. After the evacuation of the well has been completed, the well is sampled when possible, and the pump is removed from the well and the process is repeated at each well location moving from the least contaminated to most contaminated well. If sample collection is not possible due to the well being purged dry, a sample is collected after recovery using a disposable bailer and as described in Attachment 2-3 of the QAP. Sample collection follows the procedures described in Attachment 2-4 of the QAP. After the samples have been collected for a particular well, the samples are placed into a cooler that contains ice. The well is then recapped and Mill personnel proceed to the next well. If a bailer has been used it is disposed of. Decontamination of non-dedicated equipment, using the reagents in Attachment 2-2 of the QAP, is performed between each sample location, and at the beginning of each sampling day, in addition to the pre-event decontamination described above. 2.2.2 Piezometer Sampling Samples are collected from Piezometers 1, 2 and 3A, if possible. Samples are collected from piezometers using a disposable bailer after one set of field measurements have been collected. Due to the difficulty in obtaining samples from the piezometers, the purging protocols set out in the QAP are not followed. After samples are collected, the bailer is disposed of and samples are placed into a cooler containing ice for sample preservation and transit to the Mill's contract analytical laboratory, American West Analytical Laboratories ("AW AL"). 4 2.3 Field Data Attached under Tab B are copies of all Field Data Worksheets that were completed during the quarter for the nitrate investigation monitoring wells and piezometers identified in Section 2.1.1 and Table 1. 2.4 Depth to Groundwater Data and Water Table Contour Map Depth-to-groundwater measurements that were utilized for groundwater contours are included on the Quarterly Depth to Water Sheet at Tab C of this Report along with the kriged groundwater contour map for the current quarter generated from this data. All well levels used for groundwater contour mapping were measured and recorded within 5 calendar days of each other as indicated by the measurement dates in the summary sheet under Tab C. A copy of the kriged groundwater contour map generated from the previous quarter's data is provided under Tab D. 2.5 Laboratory Results 2.5.1 Copy of Laboratory Results The analytical results were provided by AW AL. Table 1 lists the dates when analytical results were reported to the Quality Assurance ("QA") Manager for each well or other sample. Analytical results for the samples collected for this quarter's nitrate investigation and a limited list of chloroform investigation nitrate and chloride results are provided under Tab G of this Report. Also included under Tab G are the results of analyses for duplicate samples and rinsate samples for this sampling effort, as identified in Table 1. See the Groundwater Monitoring Report and Chloroform Monitoring Report for this quarter for nitrate and chloroform analytical results for the groundwater monitoring wells and chloroform investigation wells not listed in Table 1. 2.5.2 Regulatory Framework As discussed in Section 1.0 above, the Request, Plan, and CA each triggered a series of actions on EFRI's part. Potential surficial sources of nitrate and chloride have been described in the December 30, 2009 CIR and additional investigations into potential sources were completed and discussed with DWMRC in 2011. Pursuant to the CA, the CAP was submitted to the Director of the Division Waste Management and Radiation Control (the "Director") on May 7, 2012. The CAP describes activities associated with the nitrate in groundwater. The CAP was approved by the Director on December 12, 2012. This quarterly report documents the monitoring consistent with the program described in the CAP. 3.0 QUALITY ASSURANCE AND DATA VALIDATION EFRI' s QA Manager performed a QA/Quality Control ("QC") review to confirm compliance of the monitoring program with the requirements of the QAP. As required in the QAP, data QA includes preparation and analysis of QC samples in the field, review of field procedures, an analyte completeness review, and QC review of laboratory data methods and data. Identification 5 of field QC samples collected and analyzed is provided in Section 3.1. Discussion of adherence to Mill sampling Standard Operating Procedures ("SOPs") is provided in Section 3.2. Analytical completeness review results are provided in Section 3.3. The steps and tests applied to check field data QA/QC, holding times, receipt temperature and laboratory data QA/QC are discussed in Sections 3.4.1 through 3.4.7 below. The analytical laboratory has provided summary reports of the analytical QA/QC measurements necessary to maintain conformance with National Environmental Laboratory Accreditation Conference certification and reporting protocol. The Analytical Laboratory QA/QC Summary Reports, including copies of the Mill's Chain of Custody and Analytical Request Record forms for each set of Analytical Results, follow the analytical results under Tab G. Results of the review of the laboratory QA/QC information are provided under Tab H and discussed in Section 3.4, below. 3.1 Field QC Samples The following QC samples were generated by Mill personnel and submitted to the analytical laboratory in order to assess the quality of data resulting from the field sampling program. Field QC samples for the nitrate investigation program consist of one field duplicate sample for each 20 samples, DI Field Blanks ("DIFB"), and equipment rinsate samples. During the qua1ter, one duplicate sample was collected as indicated in Table 1. The duplicate was sent blind to the analytical laboratory and analyzed for the same parameters as the nitrate wells. One rinsate blank sample was collected as indicated on Table 1. Rinsate samples are labeled with the name of the subsequently purged well with a terminal letter "R" added (e.g. TWN-7R). The field QC sample results are included with the routine analyses under Tab G. 3.2 Adherence to Mill Sampling SOPs The QA Manager review of Mill Personnel's adherence to the existing SOPs, confirmed that the QA/QC requirements established in the QAP and Chloroform QAP were met. 3.3 Analyte Completeness Review All analyses required by the GWDP for nitrate monitoring for the period were performed. 3.4 Data Validation The QAP and GWDP identify the data validation steps and data QC checks required for the nitrate monitoring program. Consistent with these requirements, the QA Manager performed the following evaluations: a field data QA/QC evaluation, a holding time evaluation, an analytical method check, a reporting limit evaluation, a QC evaluation of sample duplicates, a QC evaluation of control limits for analysis and blanks, a receipt temperature evaluation, and a 6 rinsate evaluation. Because no VOCs are analyzed for the nitrate contamination investigation, no trip blanks are required in the sampling program. Each evaluation is discussed in the following sections. Data check tables indicating the results of each test are provided under Tab H. 3.4.1 Field Data QA/QC Evaluation The QA Manager performs a review of all field recorded parameters to assess their adherence with QAP requirements. The assessment involved review of two sources of information: the Field Data Sheets and the Quarterly Depth to Water summary sheet. Review of the Field Data Sheets addresses well purging volumes and stability of five parameters: conductance, pH, temperature, redox potential, turbidity, and dissolved oxygen ("DO"). Review of the Depth to Water data confirms that all depth measurements used for development of groundwater contour maps were conducted within a five-day period of each other. The results of this quarter's review are provided under Tab H. Based upon the review of the field data sheets, field work was completed in compliance with the QAP purging and field measurement requirements. A summary of the purging techniques employed and field measurements taken is described below: Purging Two Ca ing Volumes with Stable Field Parameters (within 10% RPD) Wells TWN-01, TWN-04, and TWN-18 were sampled after two casing volumes were removed. Field parameters pH, specific conductivity, turbidity, water temperature, DO, and redox potential were measured during purging. All field parameters for this requirement were stable within 10% RPD. Purging a Well to Dryne and Stability of a Limited List of Field Parameters Wells TWN-03 and TWN-07 were purged to dryness before two casing volumes were evacuated. After well recovery, one set of measurements for the field parameters of pH, specific conductivity, and water temperature only were taken; the samples were collected, and another set of measurements for pH, specific conductivity, and water temperature were taken. Stabilization of pH, conductivity and temperature are required within 10% RPD under the QAP. All field parameters for this requirement were stable within 10% RPD. ContinuousJy Pumped Well. Wells TWN-02, TW4-22, TW4-24, and TW4-25 are continuously pumped wells. These wells are pumped on a set schedule per the remediation plan and are considered sufficiently evacuated to immediately collect a sample. As previously noted, TW4-22, TW4-24, and TW4-25 are chloroform investigation wells and are sampled under the chloroform program. Data for nitrate and chloride are provided here for completeness purposes. During review of the field data sheets, it was observed that sampling personnel consistently recorded depth to water to the nearest 0.01 foot. All field parameters for all wells were within the QAP required limits, as indicated below. The field data collected during the quarter were in compliance with QAP requirements. 7 3.4.2 Holding Time Evaluation QAP Table 1 identifies the method holding times for each suite of parameters. Sample holding time checks are provided in Tab H. All samples were received and analyzed within the required holding time. 3.4.3 Analytical Method Checklist All analytical methods reported by the laboratory were checked against the required methods enumerated in the QAP. Analytical method checks are provided in Tab H. All methods were consistent with the requirements of the QAP. 3.4.4 Reporting Limit Evaluation All analytical method reporting limits ("RLs") reported by the laboratory were checked against the reporting limits enumerated in the QAP. Reporting Limit Checks are provided in Tab H. All analytes were measured and reported to the required reporting limits, with the exception of several samples that had increased reporting limits due to matrix interference or required dilution due to the sample concentration. However, in all of those cases the analytical results were greater than the reporting limit used. 3.4.5 QA/QC Evaluation for Sample Duplicates Section 9 .1.4 a) of the QAP states that RPDs will be calculated for the comparison of duplicate and original field samples. The QAP acceptance limits for RPDs between the duplicate and original field sample is less than or equal to 20% unless the measured results are less than 5 times the required detection limit. This standard is based on the EPA Contract Laboratory Program National Functional Guidelines for Inorganic Data Review, February 1994, 9240.1-05- 01 as cited in the QAP. The RPDs are calculated for duplicate pairs for all analytes regardless of whether or not the reported concentrations are greater than 5 times the required detection limits. However, data will be considered noncompliant only when the results are greater than 5 times the required detection limit and the RPD is greater than 20%. All duplicate results were within 20% RPD for the quarterly samples. The duplicate results are provided under Tab H. 3.4.6 Other Laboratory QA/QC Section 9.2 of the QAP requires that the laboratory's QA/QC Manager check the following items in developing data reports: (1) sample preparation information is correct and complete, (2) analysis information is correct and complete, (3) appropriate Analytical Laboratory procedures are followed, (4) analytical results are correct and complete, (5) QC samples are within established control limits, (6) blanks are within QC limits, (7) special sample preparation and analytical requirements have been met, and (8) documentation is complete. In addition to other laboratory checks described above, EFRI's QA Manager rechecks QC samples and blanks (items (5) and (6)) to confirm that the percent recovery for spikes and the relative percent difference for spike duplicates are within the method-specific required limits, or that the case narrative 8 sufficiently explains any deviation from these limits. Results of this quantitative check are provided in Tab H. The lab QA/QC results met these specified acceptance limits. The QAP Section 8.1.2 requires that a Matrix Spike/Matrix Spike Duplicate ("MS/MSD") pair be analyzed with each analytical batch. The QAP does not specify acceptance limits for the MS/MSD pair, and the QAP does not specify that the MS/MSD pair be prepared on EFRI samples only. Acceptance limits for MS/MSDs are set by the laboratories. The review of the information provided by the laboratories in the data packages verified that the QAP requirement to analyze an MS/MSD pair with each analytical batch was met. While the QAP does not require it, the recoveries were reviewed for compliance with the laboratory established acceptance limits. The QAP does not require this level of review, and the results of this review are provided for information only. The information from the Laboratory QA/QC Summary Reports indicates that the MS/MSDs recoveries and the associated RPDs for the samples were within acceptable laboratory limits for the regulated compounds. The information from the Laboratory QA/QC Summary Reports indicates that the Laboratory Control Sample recoveries were acceptable, which indicate that the analytical system was operating properly. The QAP Section 8.1.2 requires that each analytical batch shall be accompanied by a reagent blank. All analytical batches routinely contain a blank, which is a laboratory-grade water blank sample made and carried through all analytical steps. For the Mill samples, a method blank is prepared for all analytical methods. The information from the Laboratory QA/QC Summary Reports indicates that the method blanks did not contain detections of any target analytes above the Reporting Limit. 3.4. 7 Receipt Temperature Evaluation Chain of Custody sheets were reviewed to confirm compliance with the QAP requirement in QAP Table 1 that samples be received at 6°C or lower. Sample temperatures checks are provided in Tab H. All samples were received within the required temperature limit. 3.4.8 Rinsate Check Rinsate checks are provided in Tab H. A comparison of the rinsate blank sample concentration levels to the QAP requirements -that rinsate sample concentrations be one order of magnitude lower than that of the actual well -indicated that all of the rinsate blank analytes met this criterion. All rinsate and DIFB blank samples were non-detect for the quarter. 9 4.0 INTERPRETATION OF DATA 4.1 Interpretation of Groundwater Levels, Gradients and Flow Directions. 4.1.1 Current Site Groundwater Contour Map As stated above, a listing of groundwater level readings for the current quarter (shown as depth to groundwater in feet) is included under Tab C. The data from this tab has been interpreted (interpolated by kriging) and plotted in a water table contour map, provided under the same tab. The contour map is based on the current quarter's data for all wells. The water level contour maps indicate that perched water flow ranges from generally southwesterly beneath the Mill site and tailings cells to generally southerly along the eastern and western margins of White Mesa south of the tailings management system. Perched water mounding associated with the wildlife ponds is still evident and locally changes the generally southerly perched water flow patterns. For example, northeast of the Mill site, mounding associated with formerly used wildlife ponds disrupts the generally southwesterly flow pattern, to the extent that locally north-northwester I y flow occurs near MW-19 and PIEZ-1. The impact of the mounding associated with the northern ponds, to which water has not been delivered since March 2012, is diminishing and is expected to continue to diminish as the mound decays due to reduced recharge. The perched groundwater mound associated with the southern wildlife pond is also diminishing due to reduced recharge at that location. Not only has recharge from the wildlife ponds impacted perched water elevations and flow directions at the site, but the cessation of water delivery to the northern ponds, which are generally upgradient of the nitrate and chloroform plumes at the site, resulted in changing conditions that were expected to impact constituent concentrations and migration rates within the plumes. Specifically, past recharge from the ponds helped limit many constituent concentrations within the plumes by dilution while the associated groundwater mounding increased hydraulic gradients and contributed to plume migration. Since use of the northern ponds was discontinued in March, 2012, increases in constituent concentrations in many wells, and decreases in hydraulic gradients within the plumes, are attributable to reduced recharge and the decay of the associated groundwater mound. EFRI and its consultants anticipated these changes and discussed these and other potential effects during discussions with DWMRC in March 2012 and May 2013. The impacts associated with cessation of water delivery to the northern ponds were expected to propagate downgradient (south and southwest) over time. Wells close to the ponds were generally expected to be impacted sooner than wells farther downgradient of the ponds. Therefore, constituent concentrations were generally expected to increase in downgradient wells close to the ponds before increases were detected in wells farther downgradient of the ponds. Although such increases were anticipated to result from reduced dilution, the magnitude and timing of the increases were anticipated to be and have been difficult to predict due to the complex permeability distribution at the site and factors such as pumping and the rate of decay of the groundwater mound. Because of these complicating factors, some wells completed in higher permeability materials were expected to be impacted sooner than other wells completed in lower permeability materials even though the wells completed in lower permeability materials were closer to the ponds. 10 In general, nitrate concentrations within and adjacent to the nitrate plume appear to have been impacted to a lesser extent than chloroform and nitrate concentrations within and in the vicinity of the chloroform plume. This behavior is reasonable considering that the chloroform plume is generally more directly downgradient of and more hydraulically connected (via higher permeability materials) to the wildlife ponds. Localized increases in concentrations of constituents such as nitrate and chloride within and near the nitrate plume may occur even when the nitrate plume is under control based on the Nitrate CAP requirements. Ongoing mechanisms that can be expected to increase the concentrations of nitrate and chloride locally as a result of reduced wildlife pond recharge include but are not limited to: 1) Reduced dilution -the m1xmg of low constituent concentration pond recharge into existing perched groundwater will be reduced over time. 2) Reduced saturated thicknesses -dewatering of higher permeability zones receiving primarily low constituent concentration pond water will result in wells intercepting the zones receiving a smaller proportion of the low constituent concentration water. The combined impact of the above two mechanisms was anticipated to be more evident at chloroform pumping wells MW-4, MW-26, TW4-4, TW4-19, and TW4-20; nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2; and non-pumped wells adjacent to the pumped wells. Impacts were also expected to occur over time at wells subsequently added to the chloroform pumping network: TW4-1, TW4-2, TW4-11, TW4-21 and TW4-37 (added during 2015); TW4-39 (added during the fourth quarter of 2016); TW4-41 (added during the second quarter of 2018); and TW4-40 (added during the second quarter of 2019). The overall impact was expected to be generally higher constituent concentrations in these wells over time until mass reduction resulting from pumping and natural attenuation eventually reduces concentrations. Short-term changes in concentrations at pumping wells and wells adjacent to pumping wells are also expected to result from changes in pumping conditions. In addition to changes in the flow regime caused by wildlife pond recharge, perched flow directions are locally influenced by operation of the chloroform and nitrate pumping wells. Well-defined cones of depression were typically evident in the vicinity of all chloroform pumping wells except TW4-4 and TW4-37, which began pumping in the first quarter of 2010 and the second quarter of 2015, respectively. The third quarter of 2018 was the first quarter that a well-defined cone of depression was associated with TW4-4, primarily the result of pumping at adjacent well TW4-41. The lack of well-defined capture associated with chloroform pumping well TW4-4 was consistent prior to the third quarter of 2018, even though pumping since the first quarter of 2010 has depressed the water table in the vicinity of this well. The lack of a well-defined cone of depression near TW4-4 likely resulted from 1) variable permeability conditions in the vicinity of TW4-4, and 2) persistent relatively low water levels at adjacent well TW4-14. Pumping of nitrate wells TW4-22, TW4-24, TW4-25, and TWN-2 began during the first quarter of 2013. Water level patterns near these wells are expected to be influenced by the presence of 11 and the decay of the groundwater mound associated with the northern wildlife ponds, and by the historically relatively low water level elevation at TWN-7. Although positioned up-to cross- gradient of the nitrate pumping wells, TWN-7 is also typically downgradient of TWN-3 and the northern (upgradient) extremity of the nitrate plume. Since 2012, water levels in TWN-7 have risen while water levels in nearby wells have generally dropped due to pumping and the decay of the northern groundwater mound. These factors have reduced water level differences between TWN-7 and nearby wells. Capture associated with nitrate pumping is expected to continue to increase over time as water levels decline due to pumping and to cessation of water delivery to the northern wildlife ponds. Interaction between nitrate and chloroform pumping is expected to enhance the capture of the nitrate pumping system. The long-term interaction between the nitrate and chloroform pumping systems is evolving, and changes will be reflected in data collected during routine monitoring. As discussed above, variable permeability conditions are one likely reason for the prior lack of a well-defined cone of depression near chloroform pumping well TW4-4. Changes in water levels at wells immediately south and southeast (downgradient) of TW4-4 resulting from TW4-4 pumping were expected to be muted because TW 4-4 is located at a transition from relatively high to relatively low permeability conditions south and southeast of TW4-4. As will be discussed below, the permeability of the perched zone at TW4-6, TW4-26, TW4-29, TW4-30, TW4-31, TW4-33, TW4-34, and TW4-35 is one to two orders of magnitude lower than at TW4- 4, and the permeability at TW4-27 is approximately three orders of magnitude lower than at TW4-4. Detecting water level drawdowns in wells immediately south and southeast of TW 4-4 resulting from TW 4-4 pumping has also been complicated by a general, long-term increase in water levels in this area that has been attributable to past wildlife pond recharge. Between the fourth quarter of 2007 and the fourth quarter of 2009 Uust prior to the start of TW4-4 pumping), water levels at TW4-4 and TW4-6 increased by nearly 2.7 and 2.9 feet at rates of approximately 1.2 feet/year and 1.3 feet/year, respectively. However, between the start of pumping at TW4-4 (first quarter of 2010) and the fourth quarter of 2013, the rate of increase in water level at TW4-6 was reduced to less than 0.5 feet/year suggesting that TW 4-6 is within the hydraulic influence of TW 4-4. Since the fourth quarter of 2013, water levels in all wells currently within the chloroform plume south of TW4-4 (TW4-26, TW4-29, TW4-33 and TW4-40 [installed in the first quarter of 2018]) have been trending generally downward, as has the water level in TW4-6 (located just outside the plume again this quarter). This downward trend is attributable to both reduced wildlife pond recharge and pumping. Although water levels at some of the wells marginal to the chloroform plume such as TW4-I4, TW4-27, TW4-30 and TW4-31 were generally increasing until about the first quarter of 2018, these water levels now appear to be relatively stable. These spatially variable water level trends likely result from pumping conditions, the permeability distribution, and distance from the wildlife ponds. Wells that are relatively hydraulically isolated (due to completion in lower permeability materials or due to intervening lower permeability materials) and that are more distant from pumping wells and the wildlife ponds, are expected to respond more slowly to pumping and reduced recharge than wells that are 12 less hydraulically isolated and are closer to pumping wells and the wildlife ponds. Wells that are more hydraulically isolated will also respond more slowly to changes in pumping. The previous lack of a well-defined cone of depression associated with TW4-4 was also influenced by the persistent, relatively low water level at non-pumping well TW4-14, located east of TW4-4 and TW4-6. Although water level differences among these three wells had diminished, the water level at TW4-14 was typically lower than the water level at TW4-6 and several feet lower than the water level at TW 4-4 even though TW 4-4 has been pumping since 2010. As during the previous quarter the water level at TW 4-14 is higher than water levels at both TW4-4 and TW4-6: the water level at TW4-14 (approximately 5535.2 feet above mean sea level ["ft amsl"]) is 4.4 feet higher than the water level at TW4-6 (approximately 5530.8 ft amsl), and nearly 2 feet higher than the water level at TW4-4 (approximately 5533.2 ft. amsl). This pattern is attributable to the cone of depression induced by pumping TW 4-4 and TW 4-41. The static water levels at wells TW 4-14 and downgradient well TW 4-27 (installed south of TW4-14 in the fourth quarter of 2011) were similar (within 1 to 2 feet) until the third quarter of 2014; both appeared anomalously low. Prior to the installation of TW4-27, the persistently low water level at TW 4-14 was considered anomalous because it appeared to be downgradient of all three wells TW4-4, TW4-6, and TW4-26, yet chloroform had not been detected at TW4-14. Chloroform had apparently migrated from TW4-4 to TW4-6 and from TW4-6 to TW4-26. This suggested that TW4-26 was actually downgradient of TW4-6, and TW4-6 was actually downgradient of TW4-4, regardless of the flow direction implied by the relatively low water level at TW4-14. The water level at TW4-26 (5529.1 feet amsl) is, however, lower than water levels at adjacent wells TW4-6 (5530.8 feet amsl) and TW4-23 (5532.8 feet amsl), as shown in the detail water level map under Tab C. Hydraulic tests indicate that the permeability at TW4-27 is an order of magnitude lower than at TW4-6 and three orders of magnitude lower than at TW4-4 (see Hydro Geo Chem, Inc. [HGC], September 20, 2010: Hydraulic Testing of TW4-4, TW4-6, and TW4-26, White Mesa Uranium Mill, July 2010; and HGC, November 28, 2011: Installation, Hydraulic Testing, and Perched Zone Hydrogeology of Perched Monitoring Well TW4-27, White Mesa Uranium Mill Near Blanding, Utah). Past similarity of water levels at TW4-14 and TW4-27, and the low permeability estimate at TW4-27, suggested that both wells were completed in materials having lower permeability than nearby wells. The low permeability condition likely reduced the rate of long-term water level increase at TW4-14 and TW4-27 compared to nearby wells, yielding water levels that appeared anomalously low. This behavior is consistent with hydraulic test data collected from more recently installed wells TW4-29, TW4-30, TW4-31, TW4-33, TW4-34 and TW4-35, which indicate that the permeability of these wells is one to two orders of magnitude higher than the permeability of TW4-27 (see: HGC, January 23, 2014, Contamination Investigation Report, TW4-12 and TW4-27 Areas, White Mesa Uranium Mill Near Blanding, Utah; and HGC, July 1, 2014, Installation and Hydraulic Testing of TW4-35 and TW4-36, White Mesa Uranium Mill Near Blanding, Utah [As-Built Report]). Hydraulic tests also indicate that the permeability at TW4-36 is slightly higher than but comparable to the low permeability at TW4-27, suggesting that TW4-36, TW4-14 and TW4-27 are completed in a continuous low permeability zone. 13 The current quarterly water level at TW4-27 (approximately 5528.9 ft. amsl) is more than 6 feet lower than the water level at TW4-14 (5535.2 ft. amsl). Increases in water level differences between TW4-14 and TW4-27 since 2013 are attributable to more rapid increases in water levels at TW4-14 compared to TW4-27. This behavior likely results primarily from: the relative positions of the wells; past water delivery to the northern wildlife ponds; and the permeability distribution. Past seepage from the ponds caused propagation of water level increases in all directions including downgradient to the south. The relative hydraulic isolation of TW4-14 and TW4-27 delayed responses at these locations. Until pumping started at TW4-41, water levels at both these wells were consistently lower than in surrounding higher permeability materials even though water levels in surrounding materials were generally decreasing due to reduced pond seepage and pumping. Although water levels at TW4-14 and TW4-27 appear to have stabilized, the previous rate of increase was higher at TW 4-14 due to factors that include: closer proximity to the northern pond seepage source and a smaller thickness of low permeability materials separating TW 4-14 from surrounding higher permeability materials. In addition, hydraulic gradients between TW4-14 and surrounding higher permeability materials were relatively large and were directed toward TW 4-14 prior to TW 4-41 pumping. Slowing of the rates of water level increase at TW4-14 (since 2015) and TW4-27 (since early 2014), and stabilization since about the first quarter of 2018, are attributable to changes in hydraulic gradients between these wells and surrounding higher permeability materials. In addition, water levels in this area are affected by reduced recharge at the southern wildlife pond and the decay of the associated groundwater mound. The decay of the mound is expected to contribute to changes in hydraulic gradients between the low permeability materials penetrated by TW4-14 and TW4-27 and the surrounding higher permeability materials. Because TW4-27 is closer to the southern wildlife pond than TW 4-14, changes in hydraulic gradients attributable to decay of the southern groundwater mound are expected to impact TW4-27 sooner and to a greater extent than TW4-14, consistent with the lower rate of increase in water levels at TW4-27, and the earlier reduction in the rate of increase (since early 2014) as discussed above). 4.1.2 Comparison of Current Groundwater Contour Map to Groundwater Contour Map for Previous Quarter The groundwater contour maps for the Mill site for the previous quarter, as submitted with the Nitrate Monitoring Report for the previous quarter, are attached under Tab D. A comparison of the water table contour maps for the current quarter (second quarter of 2020) to the water table contour maps for the previous quarter (first quarter of 2020) indicates the following: water level changes at the majority of site wells were small ( < 1 foot); and water level contours have not changed significantly except in the vicinities of many of the nitrate and chloroform pumping wells. Overall, total capture is similar to last quarter. The drawdown at chloroform pumping wells MW-4, TW4-20 and TW4-21 decreased by more than 2 feet this quarter. However drawdowns at chloroform pumping wells MW-26, TW4-2, TW4-37, TW4-39 and TW4-41; and nitrate pumping wells TW4-24 and TWN-2 increased by more than 2 feet this quarter. Water level changes at other nitrate and chloroform pumping wells were 2 feet or less, although both increases (decreases in drawdown) and decreases (increases in drawdown) occurred. Water level fluctuations at pumping wells typically occur in part because of fluctuations in pumping conditions just prior to and at the time the measurements are taken. 14 The reported water levels for chloroform pumping wells TW4-1, TW4-2 and TW4-11 are below the depth of the Brushy Basin contact this quarter. Although both increases and decreases in drawdown occurred in pumping wells, the overall apparent capture area of the combined pumping system is similar to last quarter. As discussed in Section 4.1.1, pumping at chloroform well TW4-4, which began in the first quarter of 2010, depressed the water table near TW4-4, but a well-defined cone of depression was not clearly evident until the third quarter of 2018, likely due to variable permeability conditions near TW4-4 and the historic persistently low water level at adjacent well TW4-14. The expanded cone of depression associated with TW4-4 and adjacent pumping well TW4-41 since the initiation of pumping at TW 4-41 in the second quaiter of 2018 has contributed to southerly expansion of total pumping system capture. Southerly expansion of capture was additionally enhanced in the second quarter of 2019 quarter by the initiation of pumping at TW4- 40. The reported water level decrease of 0.45 feet at Piezometer 3A may result from cessation of water delivery to the northern wildlife ponds as discussed in Section 4.1.1 and the consequent continuing decay of the associated perched water mound. Reported water level decreases of up to 0.53 feet at Piezometers 4 and 5 likely result primarily from reduced recharge at the southern wildlife pond. Reported water level decreases of approximately 0.3 and 0.35 feet, respectively, at TWN-1 and TWN-4 are consistent with continuing decay of the northern groundwater mound. The reported water levels at MW-20 and MW-37 decreased by approximately 2.6 and 7.1 feet, respectively, compensating for increases last quarter. Water level variability at these wells likely results from low permeability and variable intervals between purging/sampling and water level measurement. The reported water level decrease of nearly 4.1 feet at MW-22 compensates for the repmted increase last quarter that likely resulted from measurement error. As noted above, the reported water level at TW 4-20 increased ( draw down decreased) compared to last quarter. The reported drawdown decreased even though the pump control mechanism failed, causing continuous pump operation and eventual pump failure due to almost total dewatering of the well and exposure of the pump to air. Measurable water was not reported at DR-22. Although DR-22 is typically dry, measurable water was reported in the bottom of its casing between the second quarter of 2015 and the third quarter of 2016. 4.1.3 Hydrographs Attached under Tab E are hydrographs showing groundwater elevation in each nitrate contaminant investigation monitor well over time. Per the CAP, nitrate wells TWN-6, TWN-14, TWN-16, and TWN-19 have been maintained for depth to groundwater monitoring only. These hydrographs are also included in Tab E. 15 4.1.4 Depth to Groundwater Measured and Groundwater Elevation Attached in Tab F are tables showing depth to groundwater measured and groundwater elevation over time for each of the wells listed in Section 2.1.1 above. 4.2 Effectiveness of Hydraulic Containment and Capture 4.2.1 Hydraulic Containment and Control The CAP states that hydraulic containment and control will be evaluated in part based on water level data and in part on concentrations in wells downgradient of pumping wells TW4-22 and TW4-24. As per the CAP, the fourth quarter of 2013 was the first quarter that hydraulic capture associated with nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2 was evaluated. Hydraulic containment and control based on water level data is considered successful per the CAP if the entire nitrate plume up gradient of TW 4-22 and TW 4-24 falls within the combined capture of the nitrate pumping wells. Capture zones based on water level contours calculated by kriging the current quarter's water level data are provided on water level contour maps included under Tab C. The nitrate capture zones are defined by the bounding stream tubes associated with nitrate pumping wells. Each bounding stream tube represents a flow line parallel to the hydraulic gradient and therefore perpendicular to the intersected water level contours. Assuming that the stream tubes do not change over time, all flow between the bounding stream tubes associated with a particular pumping well is presumed to eventually reach and be removed by that well. Capture associated with chloroform pumping wells is also included on these maps because the influence of the chloroform and nitrate pumping systems overlap. The specific methodology for calculating the nitrate capture zones is substantially the same as that used since the fourth quarter of 2005 to calculate the capture zones for the chloroform program, as agreed to by the DWMRC and EFRI. The procedure for calculating nitrate capture zones is as follows: 1) Calculate water level contours by gridding the water level data on approximately 50-foot centers using the ordinary linear kriging method in Surfer™. Default kriging parameters are used that include a linear variogram, an isotropic data search, and all the available water level data for the quarter, including relevant seep and spring elevations. 2) Calculate the capture zones by hand from the kriged water level contours following the rules for flow nets: -From each pumping well, reverse track the stream tubes that bound the capture zone of each well, -maintain perpendicularity between each stream tube and the kriged water level contours. Compared to last quarter, both increases and decreases in water levels occurred at nitrate and chloroform pumping wells, although changes in water levels in chloroform pumping wells TW 4- 1, TW4-4, TW4-11, TW4-19 and TW4-40; and nitrate pumping wells TW4-22 and TW4-25 were less than two feet. Water level decreases occurred in chloroform pumping wells MW -26 (nearly 12.6 feet); TW4-1 (approximately 0.7 feet); TW4-2 (approximately 2.1 feet); TW4-4 16 (approximately 1.2 feet); TW4-11 (approximately 0.6 foot); TW4-37 (nearly 2.5 feet); TW4-39 (approximately 3.9 feet); and TW4-41 (nearly 12 feet); and in nitrate pumping wells TW4-24 (approximately 5.3 feet); TW4-25 (approximately 0.3 feet); and TWN-2 (nearly 11 feet). Water level increases occurred in chloroform pumping wells MW-4 (approximately 7.8 feet); TW4-19 (approximately 1.5 feet); TW4-20 (approximately 9 feet); TW4-21 (approximately 6.2 feet); and TW4-40 (approximately 0.2 feet); and in nitrate pumping well TW4-22 (approximately 0.7 feet). The overall apparent combined capture area of the nitrate and chloroform pumping systems is similar to last quarter. As noted in Section 4.1.2, the reported water level at TW4-20 increased (drawdown decreased) compared to last quarter. The reported drawdown decreased even though the pump control mechanism failed, causing continuous pump operation and eventual pump failure due to almost total dewatering of the well and exposure of the pump to air. The capture associated with nitrate pumping wells and the eight chloroform pumping wells added since the first quarter of 2015 is expected to generally increase over time as water levels continue to decline due to pumping and to cessation of water delivery to the northern wildlife ponds. Slow development of hydraulic capture is consistent with and expected based on the relatively low permeability of the perched zone at the site. Furthermore, although the perched groundwater mound has diminished, and water levels at TWN-7 have risen, the definition of capture associated with the nitrate pumping system continues to be influenced by the remaining perched groundwater mound and the historically relatively low water level at TWN-7. That pumping is likely sufficient to eventually capture the entire plume upgradient of TW4-22 and TW4-24 can be demonstrated by comparing the combined average pumping rates of all nitrate pumping wells for the current quarter to estimates of pre-pumping flow through the nitrate plume near the locations of TW4-22 and TW4-24. The pre-pumping flow calculation presented from the fourth quarter of 2013 through the second quarter of 2015 was assumed to represent a steady state 'background' condition that included constant recharge, hydraulic gradients, and saturated thicknesses; the calculation did not account for reduced recharge and saturated thickness caused by cessation of water delivery to the northern wildlife ponds since March, 2012. Because significant water level declines have occurred in upgradient portions of the nitrate plume due to reduced recharge, hydraulic gradients within the plume have been reduced independent of pumping. Changes related to reduced wildlife pond recharge have also resulted in reduced well productivity. Generally reduced productivities of nitrate pumping well TW4-24 and chloroform pumping well TW4-19 since the third quarter of 2014 are at least partly the result of reduced recharge. The pre-pumping flow through the nitrate plume near TW4-22 and TW4-24 that was presented from the fourth quarter of 2013 through the second quarter of 2015 was estimated using Darcy's Law to lie within a range of approximately 1.31 gpm to 2.79 gpm. Calculations were based on an average hydraulic conductivity range of 0.15 feet per day (ft. /day) to 0.32 ft. /day (depending on the calculation method), a pre-pumping hydraulic gradient of 0.025 feet per foot (ft. /ft.), a plume width of 1,200 feet, and a saturated thickness (at TW4-22 and TW4-24) of 56 feet. The hydraulic conductivity range was estimated by averaging the results obtained from slug test data that were collected automatically by data loggers from wells within the plume and analyzed using the KGS unconfined slug test solution available in Aqtesolve™ (see Hydro Geo Chem, Inc. [HGC], 17 August 3, 2005: Perched Monitoring Well Installation and Testing at the White Mesa Uranium Mill, April Through June 2005; HGC, March 10, 2009: Perched Nitrate Monitoring Well Installation and Hydraulic Testing, White Mesa Uranium Mill; and HGC, March 17 2009: Letter Report to David Frydenlund, Esq, regarding installation and testing of TW4-23, TW4-24, and TW4-25). These results are summarized in Table 6. Data from fourth quarter 2012 were used to estimate the pre-pumping hydraulic gradient and saturated thickness. These data are summarized in Tables 7 and 8. The average hydraulic conductivity was estimated to lie within a range of 0.15 ft. /day to 0.32 ft. /day. Averages were calculated four ways. As shown in Table 6 arithmetic and geometric averages for wells MW-30, MW-31, TW4-22, TW4-24, TW4-25, TWN-2, and TWN-3 were calculated as 0.22 and 0.15 ft. /day, respectively. Arithmetic and geometric averages for a subset of these wells (MW-30, MW-31, TW4-22, and TW4-24) were calculated as 0.32 and 0.31 ft./day, respectively. The lowest value, 0.15 ft. /day, represented the geometric average of the hydraulic conductivity estimates for all the plume wells. The highest value, 0.32 ft. /day, represented the arithmetic average for the four plume wells having the highest hydraulic conductivity estimates (MW-30, MW-31, TW4-22, and TW4-24). Pre-pumping hydraulic gradients were estimated at two locations; between TW4-25 and MW-31 (estimated as 0.023 ft. /ft.), and between TWN-2 and MW-30 (estimated as 0.027 ft. /ft.). These results were averaged to yield the value used in the calculation (0.025 ft. /ft.). The pre-pumping saturated thickness of 56 feet was an average of pre-pumping saturated thicknesses at TW4-22 and TW4-24. As discussed above the hydraulic gradient and saturated thickness used in the pre-pumping calculations were assumed to represent a steady state 'background' condition that was inconsistent with the cessation of water delivery to the northern wildlife ponds, located upgradient of the nitrate plume. Hydraulic gradients and saturated thicknesses within the plume have declined since nitrate pumping began as a result of two factors: reduced recharge from the ponds, and the effects of pumping. A more representative 'background' flow condition that accounts for reduced wildlife pond recharge was presented in Attachment N (Tab N) of the third quarter 2015 Nitrate Monitoring report. The original pre-pumping 'background' flow range of 1.31 gpm to 2.79 gpm has been recalculated to range from 0.79 gpm to 1.67 gpm, as presented in Table 9. This calculation is still considered conservative because the high end of the range assumed an arithmetic average hydraulic conductivity of a subset of plume wells having the highest conductivities. In addition, since the 'background' flow was recalculated, saturated thicknesses and hydraulic gradients within the plume have decreased, further reducing the rate of flow through the plume. The cumulative volume of water removed by nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2 during the current quarter was approximately 203,777 gallons. This equates to an average total extraction rate of approximately 1.6 gpm over the 90 day quarter. This average accounts for time periods when pumps were off due to insufficient water columns in the wells. The current quarter's pumping of 1.6 gpm, which is smaller than last quarter's average, is at the high end of the recalculated 'background' flow range of 0.79 gpm to 1.67 gpm. 18 Although TW4-22, TW4-24, TW4-25, and TWN-2 are designated nitrate pumping wells, some chloroform pumping wells are also located within the nitrate plume because the northwest portion of the chloroform plume commingles with the central portion of the nitrate plume. Chloroform pumping wells TW 4-19 and TW 4-20 are periodically within the nitrate plume; chloroform pumping well TW4-21, since pumping began in 2015, is typically within the nitrate plume; and TW4-37 is consistently within the nitrate plume. TW4-21 was outside the plume during the second quarter of 2017; the fourth quarter of 2018; the first quarter of 2019; the fourth quarter of 2019; and last quarter. TW 4-19 and TW 4-20 are both just outside the plume this quarter. Including TW4-21 and TW4-37, the volume of water removed by TW4-21, TW4-22, TW4-24, TW4-25, TW4-37, and TWN-2 this quarter is approximately 379,940 gallons or approximately 2.9 gpm, which exceeds the high end of the recalculated 'background' flow range by approximately 1.2 gpm, or a factor of approximately 1.7. Because the arithmetic average hydraulic conductivity of a subset of plume wells having the highest conductivities was used to calculate the high end of the 'background' flow range, the high end is considered less representative of actual conditions than using the geometric average conductivity of all of the plume wells. Therefore, nitrate pumping likely exceeds the actual flow through the plume by more than a factor of 1. 7 as calculated above. Nitrate pumping is therefore considered adequate at the present time even with reduced productivity at TW4-24. The CAP states that MW-5, MW-11, MW-30, and MW-31 are located downgradient of TW4-22 and TW4-24. MW-30 and MW-31 are within the plume near its downgradient edge and MW-5 and MW-11 are outside and downgradient of the plume. Per the CAP, hydraulic control based on concentration data will be considered successful if the nitrate concentrations in MW-30 and MW-31 remain stable or decline, and the nitrate concentrations in downgradient wells MW-5 and MW -11 do not exceed the 10 mg/L standard. Table 5 presents the nitrate concentration data for MW-30, MW-31, MW-5 and MW-11, which are down-gradient of pumping wells TW4-22 and TW4-24. Based on these concentration data, the nitrate plume is under control. The nitrate plume has not migrated downgradient to MW-5 or MW-11; nitrate at MW-11 was detected at a concentration of approximately 0.3 mg/L; and was detected at MW-5 at a concentration of approximately 0.14 mg/L. Between the previous and current quarters, nitrate concentrations increased at both MW-30 and MW-31. Nitrate in MW-30 increased from 16.4 mg/L to 18.1 mg/Land nitrate in MW-31 increased from 17.5 mg/L to 18.8 mg/L. Although short-term fluctuations have occurred, nitrate concentrations in MW-30 and MW-31 have been relatively stable, demonstrating that plume migration to the south is minimal or absent. MW-30 and MW-31 are located at the toe of the nitrate plume which has associated elevated chloride. Chloride is increasing at MW-31, as well as at MW-30, but at a lower rate (see Tab J and Tab K, discussed in Section 4.2.4). These increases are consistent with continuing downgradient migration of the elevated chloride associated with the nitrate plume. The increases in chloride and relatively stable nitrate at both wells suggest a natural attenuation process that is affecting nitrate but not chloride. A likely process that would degrade nitrate but leave chloride unaffected is reduction of nitrate by pyrite. The likelihood of this process in the perched zone is discussed in HGC, December 7 2012; Investigation of Pyrite in the Perched Zone, White Mesa 19 Uranium Mill Site, Blanding, Utah. A more detailed discussion is presented in HGC, December 11, 2017; Nitrate Corrective Action Comprehensive Monitoring Evaluation (CACME) Report, White Mesa Uranium Mill Near Blanding, Utah. 4.2.2 Current Nitrate and Chloride Isoconcentration Maps Included under Tab I of this Report are current nitrate and chloride iso-concentration maps for the Mill site. Nitrate iso-contours start at 5 mg/L and chloride iso-contours start at 100 mg/L because those values appear to separate the plumes from background. All nitrate and chloride data used to develop these iso-concentration maps are from the current quarter's sampling events. 4.2.3 Comparison of Areal Extent Although the plume has expanded in some areas and contracted in others, the area of the plume is smaller than last quarter, with some notable contraction of the boundary to the east away from MW-28. Recent expansion to the west has occurred due to increases in concentration at MW-28; however, MW-28 has remained outside the plume. In addition, TWN-7, which was incorporated within the plume for the first time during the second quarter of 2018, remains within the plume. TWN-7 has historically been located down-to cross-gradient of the northeastern (upgradient) extremity of the plume, but migration of the plume toward TWN-7 has been slow presumably due to the low permeability at TWN-7. TW4-18 remained outside the plume with a concentration of approximately 3.6 mg/L. TW4-18 was encompassed by an eastward-extending 'spur' in the plume during the third quarter of 2015, similar to an occurrence during the third quarter of 2013. Changes in nitrate concentrations near TW 4-18 are expected to result from changes in pumping and from the cessation of water delivery to the northern wildlife ponds. The reduction in low-nitrate recharge from the wildlife ponds appeared to be having the anticipated effect of generally increased nitrate concentrations in some wells downgradient of the ponds. However, decreasing to relatively stable nitrate concentrations at most wells in the vicinity of TW4-18 between the first quarter of 2014 and the second quarter of 2015 after previous increases suggested that conditions in this area had stabilized. Since the second quarter of 2015, concentrations at TW4-18 exceeded 10 mg/L only once (third quarter of 2015). Over this same time period, concentrations at nearby wells TW4-3 and TW4-9 remained below 10 mg/L; concentrations at TW4-5 exceeded 10 mg/L only once (first quarter of 2016); and, until the first quarter of 2019, concentrations at TW4-10 remained above 10 mg/L. Since the first quarter of 2019, concentrations at TW4-10 have remained below 10 mg/L. Although increases in concentration in the area downgradient of the wildlife ponds have been anticipated as the result of reduced dilution, the magnitude and timing of the increases are difficult to predict due to the measured variations in hydraulic conductivity at the site and other factors. Nitrate in the area directly downgradient (south to south-southwest) of the northern wildlife ponds is associated with the chloroform plume, is cross-gradient of the nitrate plume as defined in the CAP, and is within the capture zone of the chloroform pumping system. Perched water flow in the area is to the southwest in the same approximate direction as the main body of the nitrate plume. 20 Nitrate concentrations at the downgradient edge of the plume (MW-30 and MW-31) have been relatively stable, demonstrating that nitrate plume migration to the south is minimal or absent. As discussed in Section 4.2.1, stable nitrate at MW-30 and MW-31 is consistent with a natural attenuation process affecting nitrate but not chloride, as elevated chloride associated with the nitrate plume continues to migrate downgradient. With regard to chloroform, changes in the boundary of the chloroform plume are attributable in part to the initiation of nitrate pumping. Once nitrate pumping started, the boundary of the chloroform plume migrated to the west toward nitrate pumping well TW4-24, and then to the southwest to reincorporate chloroform monitoring wells TW 4-6 and TW 4-16. Concentration increases leading to the reincorporation of these wells occurred first at TW4-24, then at TW4-16 and TW 4-6. Reduced recharge at the southern wildlife pond and decay of the associated groundwater mound are also expected to influence chloroform concentrations in the vicinity of TW4-6. Subsequent contraction of the chloroform plume eastward away from TW4-24 and TW4-16 through the first quarter of 2016 is attributable in part to the start-up of additional chloroform pumping wells during the first half of 2015, and reduced productivity at TW4-24. TW4-16 is within and TW4-24 is outside the chloroform plume this quarter. In addition, due to contraction of the plume away from TW4-6, TW4-6 has been outside the plume since the third quarter of 2018. More details regarding the chloroform data and interpretation are included in the Quarterly Chloroform Monitoring Report submitted under separate cover. 4.2.4 Nitrate and Chloride Concentration Trend Data and Graphs Attached under Tab J is a table summarizing values for nitrate and chloride for each well over time. Attached under Tab K are graphs showing nitrate and chloride concentration plots in each monitor well over time. 4.2.5 Interpretation of Analytical Data Comparing the nitrate analytical results to those of the previous quarter, as summarized in the tables included under Tab J, the following observations can be made for wells within and immediately surrounding the nitrate plume: a) Nitrate concentrations have increased by more than 20% in the following wells compared to last quarter: TW4-21, TW4-25, TW4-39 and TWN-3; b) Nitrate concentrations have decreased by more than 20% in the following wells compared to last quarter: TW4-19 and TW4-20; c) Nitrate concentrations have remained within 20% in the following wells compared to last quarter: MW-11, MW-26, MW-27, MW-30, MW-31, TW4-16, TW4-18, TW4-22, TW4-24, TW4-37, TWN-1, TWN-2, TWN-4, TWN-7 and TWN-18; and d) MW-25, MW-29 and MW-32 remained non-detect 21 As indicated, nitrate concentrations for many of the wells with detected nitrate were within 20% of the values reported during the previous quarter, suggesting that variations are within the range typical for sampling and analytical error. The remaining wells had changes in concentration greater than 20%. The latter includes chloroform pumping wells TW4-19, TW4-20, TW4-21 and TW4-39; nitrate pumping well TW4-25; and non-pumping well TWN-3. TWN-3 is located within the upgradient (northern) extremity of the plume. Fluctuations in concentrations at pumping wells and wells adjacent to pumping wells likely result in part from the effects of pumping as discussed in Section 4.1.1. Concentrations at TW 4- 25 are less than 1 mg/L. MW-27, located west of TWN-2, and TWN-18, located north of TWN-3, bound the nitrate plume to the west and north; however, TWN-7 no longer bounds to plume to the northwest (See Figure 1-1 under Tab I). In addition, the southernmost (downgradient) boundary of the plume remains between MW-30/MW-31 and MW-5/MW-l 1. Nitrate concentrations at MW-5 (adjacent to MW-11) and MW-11 have historically been low ( < 1 mg/L) or non-detect for nitrate (See Table 5). The nitrate concentrations at MW-5 (0.14 mg/L) and MW-11 (0.3 mg/L) are consistent with the relative stability of the downgradient margin of the plume. MW-25, MW-26, MW-32, TW4-16, TW4-18, TW4-19, TW4-20, TW4-25, TW4-39, TWN-1 and TWN-4 bound the nitrate plume to the east. Nitrate concentrations outside the nitrate plume are typically greater than 10 mg/L at a few locations: TW4-26 (11.1 mg/L); TW4-27 (21.5 mg/L); and TW4-28 (10.2 mg/Lin the third quarter of 2019; 9.6 mg/L this quarter). In the past concentrations at TW4-10, TW4-12 and TW4-38 typically exceeded 10 mg/L. However TW4-10 dropped below 10 mg/L during the first quarter of 2019; TW4-12 dropped below 10 mg/Lin the second quarter of 2019; and TW4-38 dropped below 10 mg/L during the fust quarter of 2018. Concentrations at TW 4-18 have also occasionally exceeded 10 mg/L. Each of these wells is located southeast of the nitrate plume as defined in the CAP and is separated from the plume by a well or wells where nitrate concentrations are either non-detect, or, if detected, are less than 10 mg/L. Except for TW4-12, which dropped more than 20%, the nitrate concentrations at all these wells are within 20% of last quarter's concentrations. Since 2010, nitrate concentrations at TW4-10 and TW4-18 have been above and below 10 mg/L Concentrations were below 10 mg/L between the first quarter of 2011 and second quarter of 2013, and mostly close to or above 10 mg/L between the second quarter of 2013 and third quarter of 2015. However, concentrations at TW4-18 have been below 10 mg/L since the third quarter of 2015 and (as discussed above) the concentration at TW4-10 dropped below 10 mg/L during the first quarter of 2019. Concentrations at nearby well TW4-5 have exceeded 10 mg/L only twice since 2010, and concentrations at nearby wells TW4-3 and TW4-9 have remained below 10 mg/L. Nitrate at TW4-5, TW4-10, and TW4-18 is associated with the chloroform plume, and is within the capture zone of the chloroform pumping system. Elevated nitrate at TW4-12, TW4-26, TW4-27, TW4-28 and TW4-38 is likely related to former cattle ranching operations at the site. Elevated nitrate at recently installed well MW-38 and at MW-20 (far cross- gradient and far downgradient, respectively, of the tailings management system at the site) is also likely related to former cattle ranching operations. 22 Chloride concentrations are measured because elevated chloride (greater than 100 mg/L) is associated with the nitrate plume. Chloride concentrations at all sampled locations this quarter are within 20% of their respective concentrations during the previous quarter except at chloroform pumping wells MW-26, TW4-19, TW4-21 and TW4-37. Concentration fluctuations at pumping wells likely result in part from the effects of pumping as discussed in Section 4.1.1. TWN-7 (located upgradient [north] of the tailings management system) was positioned historically cross-to downgradient of the upgradient (northeastern) extremities of the commingled nitrate and chloride plumes. Recent increases in both nitrate and chloride at TWN- 7, which remains incorporated into both the nitrate and chloride plumes this quarter, likely result from northwesterly migration of the elevated nitrate and chloride contained within the upgradient extremities of these commingled plumes. Changes in both nitrate and chloride at TWN-7 since last quarter are less than 20%. Piezometer PIEZ-3A was installed in the second quarter of 2016 as a replacement to piezometer PIEZ-3. The chloride concentration at piezometer PIEZ-3A (88.3 mg/L) is nearly three times higher this quarter than the pre-abandonment first quarter 2016 concentration at PIEZ-3 (approximately 33 mg/L). The nitrate concentration at PIEZ-3A (approximately 12.4 mg/L) is also higher this quarter than the pre-abandonment first quarter 2016 PIEZ-3 concentration (approximately 2.2 mg/L). 4.3 Estimation of Pumped Nitrate Mass and Residual Nitrate Mass within the Plume Nitrate mass removed by pumping as summarized in Table 2 includes mass removed by both chloroform and nitrate pumping wells. Table 3 shows the volume of water pumped at each well and Table 4 provides the details of the nitrate removal for each well. Mass removal calculations begin with the third quarter of 2010 because the second quarter, 2010 data were specified to be used to establish a baseline mass for the nitrate plume. As stated in the CAP, the baseline mass is to be calculated using the second quarter, 2010 concentration and saturated thickness data "within the area of the kriged 10 mg/L plume boundary." The second quarter, 2010 data set was considered appropriate because "the second quarter, 2010 concentration peak at TWN-2 likely identifies a high concentration zone that still exists but has migrated away from the immediate vicinity of TWN-2." As shown in Table 2, since the third quarter of 2010, a total of approximately 3,293 lb. of nitrate has been removed directly from the perched zone by pumping. Prior to the first quarter of 2013, all direct nitrate mass removal resulted from operation of chloroform pumping wells MW-4, MW-26, TW4-4, TW4-19, and TW4-20. During the current quarter: • A total of approximately 86 lb. of nitrate was removed by the chloroform pumping wells and by nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2. • Of the 86 lb. removed during the current quarter, approximately 38 lb. (or 44 %) was removed by the nitrate pumping wells. The calculated nitrate mass removed directly by pumping was about the same as last quarter's approximately 87 lbs. 23 As discussed in Section 4.3.1, achievable pumping rates are expected to diminish over time as saturated thicknesses are reduced by pumping and by cessation of water delivery to the northern wildlife ponds. Attachment N (Tab N) of the third quarter 2015 Nitrate Monitoring report provides an evaluation of reduced productivity at chloroform pumping well TW 4-19 and nitrate pumping well TW4-24. Baseline mass and current quarter mass estimates (nitrate+ nitrite as N) for the nitrate plume are approximately 43,700 lb. and 30,467 lbs., respectively. Mass estimates were calculated within the plume boundaries as defined by the kriged 10 mg/L isocon by 1) gridding (kriging) the nitrate concentration data on 50-foot centers; 2) calculating the volume of water in each grid cell based on the saturated thickness and assuming a porosity of 0.18; 3) calculating the mass of nitrate+nitrite as N in each cell based on the concentration and volume of water for each cell; and 4) totaling the mass of all grid cells within the 10 mg/L plume boundary. Data used in these calculations included data from wells listed in Table 3 of the CAP. The nitrate mass estimate for the current quarter (30,467 lb) is smaller than the mass estimate for the previous quarter (32,739 lb) by 2,272 lb. Since pumping began, calculated nitrate mass within the plume has generally decreased at a rate that is on average higher than would be expected based on direct mass removal by pumping. Changes in the quarterly mass estimates are expected to result from several factors, primarily 1) nitrate mass removed directly by pumping, 2) natural attenuation of nitrate, and 3) re-distribution of nitrate within the plume and changes in saturated thicknesses. Nitrate mass removed by pumping and natural attenuation (expected to result primarily from pyrite oxidation/nitrate reduction) act to lower both nitrate mass and concentrations within the plume. Both mechanisms are expected to continuously reduce both nitrate mass and concentrations within the plume. Reductions in saturated thickness that are not accompanied by increases in concentration will also reduce nitrate mass within the plume. However, redistribution of nitrate within the plume is expected to result in both increases and decreases in concentrations at wells within the plume and therefore increases and decreases in mass estimates based on those concentrations, thus generating 'noise' in the mass estimates. In addition, because the sum of sampling and analytical error is typically about 20%, changes in the mass estimates from quarter to quarter of up to 20% could result from typical sampling and analytical error alone. Furthermore, redistribution of nitrate within the plume and changes in saturated thicknesses will be impacted by changes in pumping and in background conditions such as the decay of the perched water mound associated with the northern wildlife ponds. Cessation of water delivery to the northern wildlife ponds is expected to result in reduced saturated thicknesses and reduced dilution, which in turn is expected to result in increased nitrate concentrations in many wells. Because of quarter to quarter variations in factors that impact the mass estimates, only longer- term analyses of the mass estimates that minimize the impacts of 'noise' can provide useful information on plume mass trends. Over the long term, nitrate mass estimates are expected to trend downward as a result of direct removal by pumping and through natural attenuation. 24 The decrease in the mass estimate this quarter is attributable primarily to the apparent contraction of the western plume boundary to the east and away from MW-28. As specified in the CAP, once eight quarters of data were collected (starting with the first quarter of 2013), a regression trend line was to be applied to the quarterly mass estimates and evaluated. The trend line was to be updated quarterly and reevaluated as additional quarters of data were collected. The evaluation was to determine whether the mass estimates were increasing, decreasing, or stable. As the fourth quarter of 2014 constituted the eighth quarter as specified in the CAP, the mass estimates were plotted, and a regression line was fitted to the data and evaluated. The regression line has been updated each quarter since the fourth quarter of 2014 as shown in Figure M.1 of Tab M. The fitted line shows a decreasing trend in the mass estimates. 5.0 LONG TERM PUMP TEST AT TWN-02, TW4-22, TW4-24, and TW4- 25 OPERATIONS REPORT 5.1 Introduction Beginning in January 2013, EFRI began long term pumping of TW4-22, TW4-24, TW4-25, and TWN-02 as required by the Nitrate CAP, dated May 7, 2012 and the SCO dated December 12, 2012. In addition, as a part of the investigation of chloroform contamination at the Mill site, EFRI has been conducting a Long Term Pump Test on MW-4, TW4-19, MW-26, and TW4-20, and, since January 31, 2010, TW4-4. In anticipation of the final approval of the GCAP, beginning on January 14, 2015, EFRI began long term pumping of TW4-1, TW4-2, and TW4-11 and began long term pumping of TW4-21 and TW4-37 on June 9, 2015. In addition, EFRI is pumping TW4-39, TW4-40 and TW4-41. The purpose of the test is to serve as an interim action that will remove a significant amount of chloroform-contaminated water while gathering additional data on hydraulic properties in the area of investigation. Because wells MW-4, TW4-19, MW-26, TW4-4, TW4-20, TW4-01, TW4-02, TW4-11, TW4- 21, TW4-37, TW4-39, TW4-40 and TW4-41 are pumping wells that may impact the removal of nitrate, they are included in this report and any nitrate removal realized as part of this pumping is calculated and included in the quarterly reports. The following information documents the operational activities during the quarter. 5.2 Pumping Well Data Collection Data collected during the quarter included the following: • Measurement of water levels at MW-4, TW4-19, MW-26, and TW4-20 and, commencing regularly on March 1, 2010, TW4-4, on a weekly basis, • Measurement of water levels weekly at TW4-22, TW4-24, TW4-25, and TWN-02 commencing January 28, 2013, 25 • Measurement of water levels weekly at TW4-01, TW4-02, and TW4-11 commencing on January 14, 2015, • Measurement of water levels weekly at TW4-21 and TW4-37 commencing on June 9, 2015, and on a monthly basis selected temporary wells and permanent monitoring well, • Measurement of water levels weekly at TW4-39 commencing on December 7, 2016, • Measurement of water levels weekly at TW4-41 commencing on April 3, 2018, • Measurement of water levels weekly at TW4-40 commencing on May 13, 2019. • Measurement of pumping history, including: pumping rates total pumped volume operational and non-operational periods. • Periodic sampling of pumped water for chloroform and nitrate/nitrite analysis and other constituents 5.3 Water Level Measurements Beginning August 16, 2003, water level measurements from chloroform pumping wells MW-4, MW-26, and TW4-19 were conducted weekly. From commencement of pumping TW4-20, and regularly after March 1, 2010 for TW4-4, water levels in these two chloroform pumping wells have been measured weekly. From commencement of pumping in January 2013, water levels in wells TW4-22, TW4-24, TW4-25, and TWN-02 have been measured weekly. From the commencement of pumping in December 2016, water levels in TW4-39 have been measured; from the commencement of pumping in April 2018 water levels in TW 4-41 have been measured and from the commencement of pumping in May 2019 water levels in TW 4-40 have been measured weekly. Copies of the weekly Depth to Water monitoring sheets for MW-4, MW-26, TW4-19, TW4-20, TW4-4, TW4-22, TW4-24, TW4-25, TWN-02, TW4-01, TW4-02, TW4-ll, TW4-21, TW4-37, TW4-39, TW4-40, and TW4-41 are included under Tab C. Monthly depth to water monitoring is required for all of the chloroform contaminant investigation wells and non-pumping wells MW-27, MW-30, MW-31, TWN-1, TWN-3, TWN- 4, TWN-7, and TWN-18. Copies of the monthly depth to Water monitoring sheets are included under Tab C. 5.4 Pumping Rates and Volumes The pumping wells do not pump continuously, but are on a delay device. The wells purge for a set amount of time and then shut off to allow the well to recharge. Water from the pumping wells is either transferred to the Cell 1 evaporation pond or is used in the Mill process. The pumped wells are fitted with a flow meter which records the volume of water pumped from the well in gallons. The flow meter readings shown in Tab C are used to calculate the gallons of water pumped from the wells each quarter as required by Section 7.2.2 of the CAP. The average pumping rates and quarterly volumes for each of the pumping wells are shown in Table 3. The cumulative volume of water pumped from each of the wells is shown in Table 4. 26 Specific operational problems observed with the well or pumping equipment which occurred during the quarter are noted for each well below. 5.4.1 TW 4-19 During the routine check on May 4, 2020, the pump in TW 4-19 malfunctioned. All ancillary systems and controllers were checked and it was determined that the pump was the cause of the issue. The pump was removed and replaced within 24 hours of discovery and as such no notifications were necessary. 6.0 CORRECTIVE ACTION REPORT There are no corrective actions required during the current monitoring period. 6.1 Assessment of Previous Quarter's Corrective Actions There were no corrective actions required during the previous quarters' monitoring period. 7.0 CONCLUSIONS AND RECOMMENDATIONS As per the CAP, the current quarter is the twenty seventh quarter that hydraulic capture associated with nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2 was evaluated. While the apparent combined capture of the nitrate and chloroform pumping systems has expanded slightly in some areas and contracted in others, the overall capture area this quarter is similar to last quarter's. Capture associated with nitrate pumping wells is expected to increase over time as water levels decline due to pumping and to cessation of water delivery to the northern wildlife ponds. Furthermore, the evaluation of the long term interaction between nitrate and chloroform pumping systems requires more data to be collected as part of routine monitoring. Slow development of hydraulic capture by the nitrate pumping system is consistent with and expected based on the relatively low permeability of the perched zone at the site. Although the perched groundwater mound has diminished, and water levels at TWN-7 have risen, definition of capture associated with the nitrate pumping system continues to be influenced by the remaining perched groundwater mound and the historically relatively low water level at TWN-7. Nitrate pumping is likely sufficient to eventually capture the entire nitrate plume upgradient of TW4-22 and TW4-24 even with productivity at TW4-24 that has been reduced since the third quarter of 2014. Hydraulic gradients and saturated thicknesses within the plume have declined since nitrate pumping began as a result of two factors: reduced recharge from the ponds, and nitrate pumping. A more representative 'background' flow condition that accounts for reduced wildlife pond recharge was presented in Attachment N (Tab N) of the third quarter, 2015 Nitrate Monitoring report. The original pre-pumping 'background' flow range of 1.31 gpm to 2.79 gpm was recalculated to range from 0.79 gpm to 1.67 gpm. This calculation is still considered conservative because the high end of the calculated range assumed an arithmetic average hydraulic conductivity of a subset of plume wells having the highest conductivities. In addition, 27 since the 'background' flow was recalculated, saturated thicknesses and hydraulic gradients within the plume have decreased, further reducing the rate of flow through the plume. The current nitrate pumping of approximately 1.6 gpm, based on water removed by TW4-22, TW4-24, TW4-25, and TWN-2, is at the high end of the recalculated 'background' flow range of 0. 79 gpm to 1.67 gpm. If water removed from the nitrate plume by chloroform pumping wells TW4-21 and TW4-37 is included, the current nitrate pumping of approximately 2.9 gpm exceeds the high end of the recalculated 'background' range by approximately 1.2 gpm, or a factor of approximately 1.7. Including TW4-37 is appropriate because this well has been within the nitrate plume consistently since initiation of pumping in 2015. Including TW4-21 is appropriate because TW4-21 is once again within the plume this quarter. In addition, because the arithmetic average hydraulic conductivity of a subset of plume wells having the highest conductivities was used in recalculating the high end of the 'background' flow range, the high end is considered less representative of actual conditions than using the geometric average conductivity of all of the plume wells. Therefore, nitrate pumping likely exceeds flow through the plume by a factor greater than 1. 7 times the high end of the recalculated range. Nitrate pumping is considered adequate at the present time even with reduced productivity at TW4-24. Furthermore, as the groundwater mound associated with former water delivery to the northern wildlife ponds continues to decay, hydraulic gradients and saturated thicknesses will continue to decrease, and 'background' flow will be proportionally reduced, thereby reducing the amount of pumping needed. First quarter, 2019 nitrate concentrations at many of the wells within and adjacent to the nitrate plume were within 20% of the values reported during the previous quarter, suggesting that variations are within the range typical for sampling and analytical error. Changes in concentration greater than 20% occurred in chloroform pumping wells TW4-19, TW4-20, TW4- 21 and TW4-39; nitrate pumping well TW4-25; and non-pumping well TWN-3. TWN-3 is located within the upgradient (northern) extremity of the plume. Concentrations at TW4-25 are less than 1 mg/L. Fluctuations in concentrations at pumping wells and wells adjacent to pumping wells likely result in part from the effects of pumping as discussed in Section 4.1.1. The nitrate concentrations in well MW-11 remained at approximately 0.3 mg/L while MW-25, MW-29 and MW-32 remained non-detect. As discussed in Section 4.2.3, the area of the nitrate plume is smaller than last quarter, with some notable contraction of the western plume boundary to the east away from MW-28. MW-27, located west of TWN-2, and TWN-18, located north of TWN-3, bound the nitrate plume to the west and north; however, TWN-7 no longer bounds the plume to the west (see Figure 1-1 under Tab I), as the concentration at TWN-7 exceeded 10 mg/L again this quarter. In addition, the southernmost (downgradient) boundary of the plume remains between MW- 30/MW-31 and MW-5/MW-1 l. Nitrate concentrations at MW-5 (adjacent to MW-11) and MW- 11 have historically been low ( < 1 mg/L) or non-detect for nitrate (See Table 5). The nitrate concentration at MW-11 of approximately 0.3 mg/L is consistent with the relative stability of the 28 downgradient margin of the plume. MW-25, MW-26, MW-32, TW4-16, TW4-18, TW4-19, TW4-20, TW4-25, TW4-39, TWN-1 and TWN-4 bound the nitrate plume to the east. Although short-term fluctuations have occurred, nitrate concentrations in MW-30 and MW-31 have been relatively stable, demonstrating that plume migration is minimal or absent. Nitrate in MW-30 increased from 16.4 mg/L to 18.1 mg/Land nitrate in MW-31 increased from 17.5 mg/L to 18.8 mg/L. Based on the concentration data at MW-5, MW-11, MW-30, and MW-31, the nitrate plume is under control. Chloride is increasing at MW-31 and at MW-30, but at a lower rate. These increases are consistent with continuing downgradient migration of the elevated chloride associated with the nitrate plume. The increasing chloride and relatively stable nitrate at both wells suggests a natural attenuation process that is affecting nitrate but not chloride. A likely process that would degrade nitrate but leave chloride unaffected is reduction of nitrate by pyrite. The likelihood of this process in the perched zone is discussed in HGC, December 7 2012; Investigation of Pyrite in the Perched Zone, White Mesa Uranium Mill Site, Blanding, Utah. A more detailed discussion is presented in HGC, December 11, 2017; Nitrate Corrective Action Comprehensive Monitoring Evaluation (CA CME) Report, White Mesa Uranium Mill Near Blanding, Utah. Nitrate mass within the plume boundary has been calculated on a quarterly basis beginning with the first quarter of 2013. Mass within the plume is expected to be impacted by factors that include pumping, natural attenuation, redistribution of nitrate within the plume, and changes in saturated thickness. Nitrate mass removal by pumping and natural attenuation (expected to result primarily from pyrite oxidation/nitrate reduction) act to lower nitrate mass within the plume. Reductions in saturated thickness that are not accompanied by increases in concentration will also reduce nitrate mass within the plume. Changes resulting from redistribution of nitrate within the plume are expected to result in both increases and decreases in concentrations at wells within the plume and therefore increases and decreases in mass estimates based on those concentrations, thus generating 'noise' in the mass estimates. Furthermore, because the sum of sampling and analytical error is typically about 20%, changes in the mass estimates from quarter to quarter of up to 20% could result from typical sampling and analytical error alone. Longer-term analyses of the mass estimates that minimize the impact of these quarter to quarter variations are expected to provide useful information on plume mass trends. Over the long term, nitrate mass estimates are expected to trend downward as a result of direct removal by pumping and through natural attenuation. As specified in the CAP, once eight quarters of data were collected (starting with the first quarter of 2013), a regression trend line was to be applied to the quarterly mass estimates and evaluated. The trend line was to be updated quarterly and reevaluated as additional quarters of data were collected. As the fourth quarter of 2014 constituted the eighth quarter as specified in the CAP, the mass estimates were plotted, and a regression line was fitted to the data and evaluated. The regression line was updated this quarter as shown in Figure M.1 of Tab M. The fitted line shows a decreasing trend in the mass estimates. 29 During the current quarter, a total of approximately 86 lb. of nitrate was removed by the chloroform pumping wells and by nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN- 2. Of the 86 lb. removed during the current quarter, approximately 38 lb. ( or 44 % ) was removed by the nitrate pumping wells. The baseline nitrate (nitrate+nitrite as N) plume mass calculated as specified in the CAP (based on second quarter, 2010 data) was approximately 43,700 lb. The mass estimate for the current quarter (30,467 lb) is smaller than the mass estimate for the previous quarter (32,739 lb) by 2,272 lb. or approximately 7 %. The current quarter's estimate is smaller than the baseline estimate by approximately 13,233 lb. The quarterly difference is attributable primarily to the apparent contraction of the western plume boundary eastward away from MW-28. Nitrate concentrations outside the nitrate plume are typically greater than 10 mg/L at a few locations: TW4-26 (11.1 mg/L); TW4-27 (21.5 mg/L); and TW4-28 (10.2 mg/Lin the third quarter of 2019; 9.6 mg/L this quarter) In the past concentrations at TW4-10, TW4-12 and TW4-38 typically exceeded 10 mg/L. However TW4-10 dropped below 10 mg/L during the first quarter of 2019; TW4-12 dropped below 10 mg/Lin the second quarter of 2019; and TW4-38 dropped below 10 mg/L during the first quarter of 2018. Each of these wells is located southeast of the nitrate plume as defined in the CAP and is separated from the plume by a well or wells where nitrate concentrations are either non-detect, or, if detected, are less than 10 mg/L. Except for TW4-12, which dropped more than 20%, the nitrate concentrations at all these wells are within 20% of last quarter's concentrations. Since 2010, nitrate concentrations at TW 4-10 and TW 4-18 have been above and below 10 mg/L. Concentrations were below 10 mg/L between the first quarter of 2011 and second quarter of 2013, and mostly close to or above 10 mg/L between the second quarter of 2013 and third quarter of 2015. However, concentrations at TW4-18 have been below 10 mg/L since the third quarter of 2015 and (as discussed above) the concentration at TW4-10 dropped below 10 mg/L during the first quarter of 2019. Concentrations at nearby well TW4-5 have exceeded 10 mg/L only twice since 2010, and concentrations at nearby wells TW4-3 and TW4-9 have remained below 10 mg/L. Nitrate at TW4-5, TW4-10, and TW4-18 is associated with the chloroform plume, and is within the capture zone of the chloroform pumping system. Elevated nitrate at TW4-12, TW4-26, TW4-27, TW4-28 and TW4-38 is likely related to former cattle ranching operations at the site. Elevated nitrate at recently installed well MW-38 and at MW-20 (far cross- gradient and far downgradient, respectively, of the tailings management system at the site) is also likely related to former cattle ranching operations. Increases in both nitrate and chloride concentrations at wells near the northern wildlife ponds (for example TW4-18) were anticipated as a result of reduced dilution caused by cessation of water delivery to the northern wildlife ponds. However, decreasing nitrate concentrations at TW4-10 and TW4-18 from the first through third quarters of 2014 after previously increasing trends (interrupted in the first quarter of 2014) suggested that conditions in this area had stabilized. The temporary increase in nitrate concentration at TW 4-18 in the third quarter of 2015 and the generally increased nitrate at TW4-5 and TW4-10 during the three quarters following the second quarter of 2015 suggested the continuing impact of reduced wildlife pond recharge on downgradient wells. However, since the first quarter of 2016, concentrations at TW4-5, TW4-10 and TW 4-18 have been stable to decreasing. 30 EFRI and its consultants have raised the issues and potential effects associated with cessation of water delivery to the northern wildlife ponds in March, 2012 during discussions with DWMRC in March 2012 and May 2013. While past recharge from the northern ponds has helped limit many constituent concentrations within the chloroform and nitrate plumes by dilution, the associated groundwater mounding has increased hydraulic gradients and contributed to plume migration. Since use of the northern wildlife ponds ceased in March 2012, the reduction in recharge and decay of the associated groundwater mound was expected to increase many constituent concentrations within the plumes while reducing hydraulic gradients and rates of plume migration. Reduced recharge and decay of the groundwater mound associated with the southern wildlife pond may also have an impact on water levels and concentrations at wells within and marginal to the downgradient (southern) extremity of the chloroform plume. The net impact of reduced wildlife pond recharge is expected to be beneficial even though temporarily higher concentrations were also expected until continued mass reduction via pumping and natural attenuation ultimately reduces concentrations. Temporary increases in nitrate concentrations are judged less important than reduced nitrate migration rates. The actual impacts of reduced recharge on concentrations and migration rates will be defined by continued monitoring. Nitrate mass removal from the perched zone was increased substantially by the start-up of nitrate pumping wells TW4-22, TW4-24, TW4-25, and TWN-2 during the first quarter of 2013. Continued operation of these wells is therefore recommended. Pumping these wells, regardless of any short term fluctuations in concentrations detected at the wells, helps to reduce downgradient nitrate migration by removing nitrate mass and reducing average hydraulic gradients, thereby allowing natural attenuation to be more effective. Continued operation of the nitrate pumping system is expected to eventually reduce nitrate concentrations within the plume and to further reduce or halt downgradient nitrate migration. 8.0 ELECTRONIC DATA FILES AND FORMAT EFRI has provided to the Director an electronic copy of all laboratory results for groundwater quality monitoring conducted under the nitrate contaminant investigation during the quarter, in Comma Separated Values ("CSV") format. A copy of the transmittal e-mail is included under Tab L. 31 9.0 SIGNATURE AND CERTIFICATION This document was prepared by Energy Fuels Resources (USA) Inc. Energy Fuels Resources (USA) Inc. By: Scott Bakken\ Di.gitally signed by Scott Bakken : Date: 2020.08.14 17:37:35 -06'00' Scott A. Bakken Date Senior Director Regulatory Affairs 32 Certification: I certify, under penalty of law, that this document and all attachments were prepared under my direction or supervision in accordance with a system designed to assure that qualified personnel properly gather and evaluate the information submitted. Based on my inquiry of the person or persons who manage the system, or those persons directly responsible for gathering the information, the information submitted is, to the best of my knowledge and belief, true, accurate, and complete. I am aware that there are significant penalties for submitting false information, including the possibility of fine and imprisonment for knowing violations. Scott Bakken'. DigitallysignedbyScottBakken , ' D<1te: 2020.08.14 17:38:02 -06'00' Scott Bakken Senior Director Regulatory Affairs Energy Fuels Resources (USA) Inc. 33 Tables Table 1 Summary of Well Sampling and Constituents for the Period Sample Collection ffimJ. Date Date of Lab Report Piezometer 01 5/20/2020 6/10/2020 Piezometer 02 5/20/2020 6/10/2020 Piezometer 03A 5/20/2020 6/10/2020 TWN-01 5/20/2020 6/10/2020 TWN-02 5120/2020 6/10/2020 TWN-03 5/21/2020 6/10/2020 TWN-04 5/20/2020 6/10/2020 TWN-07 5/21/2020 6/10/2020 TWN-18 5/20/2020 6/10/2020 TWN-18R 5/20/2020 6/10/2020 TW4-22 5/2?/-2020 6/12/2020 TW-4-24 5/2712020 6/12/-2020 TW4-21 5/27/'J.020' 6/12/2020 TWN-60 5/20/2020 6/12/2020 TW4-60 5/27/2020 6/10/2020 TWN-65 5/20/2020 6/10/2020 Note: All wells were sampled for Nitrate and Chloride. Multiple dates shown for a single laboratory depict resubmission dates for the data. Resubmissions were required to correct reporting errors. Dates in Italics are the original laboratory submission dates. TWN-60 is a DI Field Blank. TWN-65 is a duplicate of TWN-04 TW4-60 is the chloroform program DI Field Blank. Continuously pum.(!l!d well. Table 2 Nitrate Mass Removal Per Well Per ( :}uarter MW-4 MW-26 TW4-19 TW4-20 TW4-4 TW4-22 TW4-24 TW4-25 TWN-02 TW4-01 TW4-02 TW4-11 TW4-21 TW4-37 TW4-39 TW4-40 TW4-41 Qtr. Quarter (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) (lbs.) Totals (lbs.) Q3 2010 3.20 0.3 5.8 1.7 4.7 NA NA NA NA NA NA NA NA NA NA NA NA 15.69 Q4 2010 3.76 0.4 17.3 1.4 5.1 NA NA NA NA NA NA NA NA NA NA NA NA 27.97 QI 2011 2.93 0.2 64.5 1.4 4.3 NA NA NA NA NA NA NA NA NA NA NA NA 73.30 Q2 2011 3.51 0.1 15.9 2.7 4.7 NA NA NA NA NA NA NA NA NA NA NA NA 27.01 Q3 2011 3.49 0.5 3.5 3.9 5.4 NA NA NA NA NA NA NA NA NA NA NA NA 16.82 Q4 2011 3.82 0.8 6.2 2.5 6.4 NA NA NA NA NA NA NA NA NA NA NA NA 19.71 QI 2012 3.62 0.4 0.7 5.0 6.0 NA NA NA NA NA NA NA NA NA NA NA NA 15.86 Q2 2012 3.72 0.6 3.4 2.1 5.2 NA NA NA NA NA NA NA NA NA NA NA NA 15.03 Q3 2012 3.82 0.5 3.6 2.0 4.7 NA NA NA NA NA NA NA NA NA NA NA NA 14.67 Q4 2012 3.16 0.4 5.4 1.8 4.2 NA NA NA NA NA NA NA NA NA NA NA NA 14.92 QI 2013 2.51 0.4 14.1 1.4 3.6 8.1 43.4 7.5 14.8 NA NA NA NA NA NA NA NA 95.73 Q2 2013 2.51 0.4 5.6 1.6 3.4 10.7 37.1 6.4 23.9 NA NA NA NA NA NA NA NA 91.71 Q3 2013 2.97 0.4 48.4 1.4 3.8 6.3 72.8 6.9 33.4 NA NA NA NA NA NA NA NA 176.53 Q4 2013 3.08 0.3 15.8 l.6 3.9 9.4 75.2 6.4 46.3 NA NA NA NA NA NA NA NA 162.07 Ql 2014 2.74 0.4 4.1 1.2 3.6 11.2 60.4 2.3 17.2 NA NA NA NA NA NA NA NA 103.14 Q2 2014 2.45 0.3 3.3 0.9 3.0 9.5 63.4 1.3 17.8 NA NA NA NA NA NA NA NA 101.87 Q3 2014 2.31 0.1 4.1 0.6 3.1 8.5 56.2 1.6 16.4 NA NA NA NA NA NA NA NA 92.99 Q4 2014 2.67 0.2 7.8 1.0 3.8 11.0 53.2 0.9 28.0 NA NA NA NA NA NA NA NA 108.57 Ql 2015 3.67 0.5 4.3 1.3 2.4 12.7 26.7 8.6 19.2 1.45 1.07 0.72 NA NA NA NA NA 82.61 Q2 2015 1.28 0.2 0.6 0.9 3.6 9.1 16.6 0.9 21.4 1.22 0.79 0.37 3.4 8.6 NA NA NA 68.86 Q3 2015 3.58 0.3 11.3 1.4 3.5 13.3 14.0 1.7 20.2 1.24 0.68 0.29 15.4 31.9 NA NA NA I 18.63 Q4 2015 3.68 0.2 10.0 0.8 3.1 I I.I 26.6 1.7 17.5 0.3 0.9 0.3 16.1 32.3 NA NA NA 124.50 QI 2016 3.91 0.23 15.28 1.23 3.21 6.36 24.30 0.81 34.33 0.02 0.93 0.22 15.29 26.45 NA NA NA 132.55 Q2 2016 3.66 0.21 1.31 1.48 3.36 12.92 13.17 1.01 19.24 0.02 1.15 0.25 14.46 27.76 NA NA NA 99.98 Q3 2016 3.30 0.22 9.08 1.15 3.02 11.33 14.86 1.56 12.47 0.72 0.59 0.22 15.20 27.42 NA NA NA 101.12 Q4 2016 3.48 0.18 8.76 1.23 1.79 12.14 26.49 1.02 12.14 0.10 1.00 0.23 14.68 22.20 0.62 NA NA 106.06 QI 2017 3.19 0.17 10.23 1.36 1.35 14.02 34.16 0.02 10.35 0.63 0.79 0.20 8.02 26.16 5.54 NA NA 116.19 Q2 2017 2.94 0.20 0.22 1.02 1.37 13.99 17.58 0.83 8.88 0.87 0.77 0.19 4.85 24.26 2.15 NA NA 80.12 Q3 2017 3.65 0.36 1.05 1.31 1.29 13.56 18.55 1.27 9.31 0.73 0.82 0.18 18.24 20.81 2.23 NA NA 93.37 Q4 2017 4.67 0.23 0.34 1.06 1.32 15.89 28.04 1.26 10.37 0.68 0.47 0.17 17.84 22.35 1.51 NA NA 106.21 QI 2018 3.92 0.35 7.89 1.13 1.18 12.47 36.31 2.18 7.09 0.51 0.40 0.17 15.54 21.22 1.65 NA NA 111.99 Q22018 3.94 0.20 0.46 J.16 0.96 14.07 14.89 1.12 7.22 0.40 0.47 0.16 13.73 19.96 1.38 NA 4.02 84.14 Q3 2018 3.63 0.60 2.25 0.85 0.78 9.82 14.99 0.75 6.48 0.35 0.60 0.13 0.22 16.42 1.69 NA 2.30 61.86 Q4 2018 3.81 0.39 0.21 1.04 0.77 15.27 32.56 0.61 6.30 0.38 0.45 0.14 15.43 17.38 1.97 NA 1.78 98.49 QI 2019 4.71 0.41 6.38 0.82 1.01 15.69 32.04 0.48 7.10 0.40 0.53 0.15 9.25 19.49 0.85 NA 1.79 101.08 Q2 2019 4.07 0.57 7.53 1.08 1.24 16.15 14.74 0.60 16.35 0.11 0.51 0.15 15.61 16.91 2.42 2.4 1.26 101.72 Q3 2019 3.74 0.62 0.28 1.17 0.77 14.95 16.54 0.40 8.01 0.13 0.56 0.12 13.26 14.55 0.54 3.3 1.25 80.19 Q4 2019 3.59 0.18 0.44 0.68 0.78 12.02 28.83 0.60 5.17 0.30 0.40 0.12 5.55 14.20 0.41 2.6 1.08 76.97 QI 2020 5.33 0.24 8.16 0.78 0.55 11.91 26.73 0.43 4.44 0.38 0.67 0.1 I 7.95 15.48 0.29 2.5 0.88 86.86 Q2 2020 4.28 0.62 1.30 6.08 0.93 12.77 20.05 0.64 4.04 0.04 0.43 0.13 14.26 15.39 1.56 2.4 0.98 85.95 Well Totals 138.3 14.1 336.9 63.4 117.1 356.3 960.4 61.9 465.3 10.9 15.0 4.7 254.2 441.2 24.8 13.3 15.3 3293.02 (pounds) Table 3 Well Pumping Rates and Volumes Pumping Well Volume of Water Pumped Name During the Quarter (gals) Average Pump Rate (gom) MW-4 101850.7 4.0 MW-26 25418.4 11.0 TW4-19 136619.7 17.2 TW4-20 100713.8 3.2 TW4-4 15347.0 14.7 TWN-2 30078.9 16.7 TW4-22 25295.3 18.0 TW4-24 57634.7 16.3 TW4-25 90767.9 I 1.6 TW4-0l 9600.2 12.8 TW4-02 14155.6 16.1 TW4-11 2003.9 16.5 TW4-21 110999.1 16.7 TW4-37 65163.8 18.0 TW4-39 37352.7 18.0 TW4-40 100757.1 18.0 Table4 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped MW-4 MW-26 Total Total Pumped Total Pumped Total Total Total Pumped Cone Cone Pumped Total Total Quarter (gal) Cone (mg/L) Cone (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 79859.1 4.80 4800 302266.7 1450880129 1450.9 3.20 63850.0 0.60 600 241672.3 145003350 145 0.32 Q4 2010 90042.2 5.00 5000 340809.7 1704048635 1704.0 3.76 60180.0 0.70 700 227781.3 159446910 159 0.35 Ql 2011 76247.6 4.60 4600 288597.2 1327546964 1327.5 2.93 55130.0 0.50 500 208667.1 104333525 104 0.23 Q2 2011 85849.3 4.90 4900 324939.6 1592204042 1592.2 3.51 55800.6 0.30 300 211205.3 6.34E+07 63 0.14 Q3 2011 85327.7 4.90 4900 322965.3 1582530188 1582.5 3.49 65618.0 0.90 900 248364.1 223527717 224 0.49 Q42011 89735.0 5.10 5100 339647.0 1732199573 1732.2 3.82 50191.3 2.00 2000 189974.1 379948141 380 0.84 Ql 2012 90376.4 4.80 4800 342074.7 1641958435 1642.0 3.62 31440.1 1.70 1700 119000.8 202301323.5 202 0.45 Q2 2012 90916.5 4.90 4900 344118.8 1686181940 1686.2 3.72 26701.2 2.50 2500 101064.1 252660294.3 253 0.56 Q3 2012 91607.0 5.00 5000 346732.5 1733662475 1733.7 3.82 25246.0 2.60 2600 95556.1 248445886 248 0.55 Q4 2012 78840.0 4.80 4800 298409.4 1432365120 1432.4 3.16 30797.0 1.46 1460 116566.6 170187301. 7 170 0.38 Ql 2013 62943.7 4.78 4780 238241.9 1138796304 1138.8 2.51 22650.7 2.27 2270 85732.9 194613681.9 195 0.43 Q2 2013 71187.3 4.22 4220 269443.9 1137053387 1137.1 2.51 25343.4 2.11 2110 95924.8 202401262.6 202 0.45 Q3 2013 72898.8 4.89 4890 275922.0 1349258375 1349.3 2.97 25763.0 1.98 1980 97513.0 193075650.9 193 0.43 Q42013 70340.4 5.25 5250 266238.4 1397751674 1397.8 3.08 24207.6 1.38 1380 91625.8 126443557.1 126 0.28 Ql 2014 69833.8 4.70 4700 264320.9 1242308385 1242.3 2.74 23263.1 2.12 2120 88050.8 186667767 187 0.41 Q2 2014 71934.9 4.08 4080 272273.6 1110876274 1110.9 2.45 23757.5 1.42 1420 89922.1 127689435.3 128 0.28 Q3 2014 74788.2 3.70 3700 283073.3 1047371347 1047.4 2.31 24062.4 0.70 700 91076.2 63753328.8 64 0.14 Q42014 63093.0 5.07 5070 238807.0 1210751515 1210.8 2.67 21875.8 0.93 934 82799.9 77335109.4 77 0.17 Ql 2015 76454.3 5.75 5750 289379.5 1663932272 1663.9 3.67 24004.9 2.68 2680 90858.5 243500904.6 244 0.54 Q2 2015 60714.7 2.53 2530 229805.1 581407002.9 581.4 1.28 27804.6 0.85 845 105240.4 88928147.3 89 0.20 Q3 2015 89520.8 4.79 4790 338836.2 1623025532 1623.0 3.58 21042.0 1.75 1750 79644.0 139376947.5 139 0.31 Q42015 99633.4 4.43 4430 377112.4 1670608016 1670.6 3.68 19355.6 1.11 1110 73260.9 81319650.1 81 0.18 Ql 2016 90882.1 5.15 5150 343988.7 1771542055 1771.5 3.91 19150.8 1.45 1450 72485.8 105104378.1 105 0.23 Q2 2016 96540.5 4.54 4540 365405.8 1658942298 1658.9 3.66 22105.7 1.12 1120 83670.1 93710483.4 94 0.21 Q3 2016 79786.4 4.95 4950 301991.5 1494858044 1494.9 3.30 17149.5 1.57 1570 64910.9 101910046.3 102 0.22 Q4 2016 85414.0 4.88 4880 323292.0 1577664911 1577.7 3.48 18541.6 1.18 1180 70180.0 82812348.1 83 0.18 Ql 2017 76642.3 4.99 4990 290091.1 1447554616 1447.6 3.19 26107.0 0.768 768 98815.0 75889916.2 76 0.17 Q2 2017 72299.8 4.88 4880 273654.7 1335435146 1335.4 2.94 25921.8 0.922 922 98114.0 90461120.0 90 0.20 Q3 2017 95349.3 4.59 4590 360897.1 1656517691 1656.5 3.65 27489.9 1.56 1560 104049.3 162316863.5 162 0.36 Q4 2017 106679.8 5.25 5250 403783.0 2119860976 2119.9 4.67 26445.8 1.04 1040 100097.4 104101247.1 104 0.23 Ql 2018 105060.4 4.47 4470 397653.6 1777511655 1777.5 3.92 27004.7 1.57 1570 102212.8 160474079.5 160 0.35 Q2 2018 101786.2 4.64 4640 385260.8 1787509959 1787.6 3.94 25554.7 0.90 901 100888.0 90900123.5 91 0.20 Q3 2018 95480.5 4.55 4550 351393.8 1544341817.5 1544.3 3.63 25536.1 2.80 2800 96554.1 270631587.8 271 0.60 Q4 2018 102844.8 4.44 4440 389267.5 172834 7833.9 1728.3 3.81 23791.3 1.96 1960 90050.1 176498138.2 176 0.39 Ql 2019 111746.9 5.05 5050 422961.9 2135957801.0 2136.0 4.71 25798.5 1.85 1850 101432.3 187649796.5 188 0.41 Q2 2019 94540.7 5.16 5160 357835.5 1846436595.4 1846.4 4.07 24050.2 2.83 2830 91030.0 257614919.8 258 0.57 Q3 2019 95517.8 4.59 4590 351534.9 1595598554.4 1595.5 3.74 24181.1 3.08 3080 91525.5 281898427 .5 282 0.62 Q4 2019 99220.8 4.34 4340 375550.9 1629890815.6 1629.9 3.59 22384.8 0.977 977 84725.5 82777759.2 83 0.18 Ql 2020 102597.0 5.22 5220 388329.6 2415410391.9 2415.4 5.33 24107.0 1.17 1170 91245.0 105755644.2 107 0.24 Table4 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped MW-4 MW-26 Total .. Total Pum~ Tgttll Purn~ iotl:11 Total 'f~~i;>'1:1in~ Qem ~~(nc Pumped tot.'i! "fQtal Quarter ,(gal) Cone (111~) Cone (tig/l) (litel'.S) Total (ug) (grams) (pounds) ·'~al) @lg/l,} {i!.~ 111~rs> Total {!!.q) '.fl!Jf!Ims) (P/;!UA1:Jsj Q2 2020 101850.7 5.04 5040 385504.9 1942944502.7 1942.9 4.28 25418.4 2.930 2930 96208.6 281891326.9 282 0.62 Totals Since Q3 2010 3456384.08 138.3 1180923.72 14.1 Table4 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-19 TW4-ZO Total Total Pumped Cone Cone Pumped Total Total Total Pumped Cone Cone Total Pumped Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) Total (grams) (pounds) Q3 2010 116899.2 5.90 5900 442463.5 2610534485 2611 5.76 39098.3 5.30 5300 147987.1 784331447.2 784 1.73 Q4 2010 767970.5 2.70 2700 2906768.3 7848274525 7848 17.30 36752.5 4.60 4600 139108.2 639897777.5 640 1.41 Ql 2011 454607.9 17.00 17000 1720690.9 29251745326 29252 64.49 37187.5 4.40 4400 140754.7 619320625 619 1.37 Q2 2011 159238.9 12.00 12000 602719.2 7232630838 7233 15.95 67907.7 4.80 4800 257030.6 1233747094 1234 2.72 Q3 2011 141542.6 3.00 3000 535738.7 1607216223 1607 3.54 72311.2 6.50 6500 273697.9 1779036298 1779 3.92 Q4 2011 147647.2 5.00 5000 558844.7 2794223260 2794 6.16 72089.3 4.20 4200 272858.0 1146003602 1146 2.53 Ql 2012 148747.0 0.60 600 563007.4 337804437 338 0.74 76306.0 7.90 7900 288818.2 2281663859 2282 5.03 Q2 2012 172082.0 2.40 2400 651330.5 1563193161 1563 3.45 22956.4 11.00 11000 86890.1 955790963.1 956 2.11 Q3 2012 171345.0 2.50 2500 648540.8 1621352063 1621 3.57 22025.0 10.80 10800 83364.6 900337950 900 1.98 Q4 2012 156653.0 4.10 4100 592931.6 2431019581 2431 5.36 20114.0 11.00 11000 76131.5 837446390 837 1.85 Ql 2013 210908.0 7.99 7990 798286.8 6378311372 6378 14.06 18177.0 9.07 9070 68799.9 624015501.2 624 1.38 Q2 2013 226224.0 2.95 2950 856257.8 2525960628 2526 5.57 20252.4 9.76 9760 76655.3 748156059.8 748 1.65 Q3 2013 329460.1 17.60 17600 1247006.5 21947314022 21947 48.39 19731.0 8.65 8650 74681.8 645997872.8 646 1.42 Q4 2013 403974.0 4.70 4700 1529041.6 7186495473 7186 15.84 19280.2 9.64 9640 72975.6 703484369.5 703 1.55 Ql 2014 304851.0 1.62 1620 1153861.0 1869254877 1869 4.12 18781.6 7.56 7560 71088.4 537427971.4 537 1.18 Q2 2014 297660.0 1.34 1340 1126643.1 1509701754 1510 3.33 18462.4 5.95 5950 69880.2 415787094.8 416 0.92 Q3 2014 309742.0 1.60 1600 1172373.5 1875797552 1876 4.14 17237.9 4.30 4300 65245.5 280555441.5 281 0.62 Q4 2014 198331.0 4.72 4720 750682.8 3543222981 3543 7.81 16341.8 7.67 7670 61853.7 474417978.7 474 1.05 Ql 2015 60553.0 8.56 8560 229193.1 1961892979 1962 4.33 15744.7 9.80 9800 59593.7 584018157.1 584 1.29 Q2 2015 75102.8 0.92 916 284264.1 260385913.8 260 0.57 18754.1 5.76 5760 70984.3 408869386.6 409 0.90 Q3 2015 116503.9 11.60 11600 440967.3 5115220233 5115 11.28 17657.3 9.27 9270 66832.9 619540802.2 620 1.37 Q4 2015 112767.7 10.6 10600 426825.7 4524352892 4524 9.97 15547.4 6.23 6230 58846.9 366616243.1 367 0.81 Ql 2016 116597.0 15.7 15700 441319.6 6928718427 6929 15.28 14353.5 10.30 10300 54328.0 559578374.3 560 1.23 Q2 2016 123768.0 1.27 1270 468461.9 594946587.6 595 1.31 15818.3 11.20 11200 59872.3 670569373.6 671 1.48 Q3 2016 103609.0 10.5 10500 392160.1 4117680683 4118 9.08 12186.6 11.30 11300 46126.3 521226975.3 521 1.15 Q4 2016 104919.4 10.0 10000 397119.9 3971199290 3971 8.76 12879.6 11.40 11400 48749.3 555741860.4 556 1.23 Ql 2017 110416.7 11.1 11100 417927.2 4638992025 4639 10.23 13552.8 12.00 12000 51297.3 615568176 616 1.36 Q2 2017 109943.0 0.243 243 416134.3 101120624 101 0.22 12475.3 9.76 9760 47219.0 460857542.5 461 1.02 Q3 2017 112626.4 1.12 1120 426290.9 477445834.9 477 1.05 14556.8 10.80 10800 55097.5 595052870.4 595 1.31 Q4 2017 108891.2 0.38 377 412153.2 155381753.4 155 0.34 14271.0 8.91 8910 54015.7 481280198.9 481 1.06 Ql 2018 109856.3 8.61 8610 415806.1 3580090482 3580 7.89 14258.4 9.50 9500 53968.0 512696418 513 1.13 Q2 2018 111271.4 0.49 494 421162.2 208054151.0 208 0.46 13367.6 10.40 10400 50596.4 526202206.4 526 1.16 Q3 2018 105821.8 2.55 2550 400535.5 1021365558.2 1021 2.25 12443.6 8.14 8140 47099.0 383385763.5 383 0.85 Q4 2018 107197.4 0.233 233 405742.2 94537923.0 95 0.21 12841.1 9.72 9720 48603.6 472426637.2 472 1.04 Ql 2019 116132.8 6.58 6580 439562.6 2892322223.8 2892 6.38 14623.9 6.70 6700 55351.3 370853777.7 371 0.82 Q2 2019 100704.0 8.96 8960 381164.6 3415235174.4 3415 7.53 13439.2 9.59 9590 50867.4 487818097.5 488 1.08 Q3 2019 101026.8 0.332 332 382386.4 126952297 .4 127 0.28 13787.0 10.20 10200 52183.8 532274709.0 532 1.17 Q4 2019 98806.8 0.535 535 373983.7 200081299.8 200 0.44 8317.7 9.75 9750 31482.5 306953952.3 307 0.68 Ql 2020 96857.9 10.1 10100 366607.2 3702732230.2 3703 8.16 9505.1 9.81 9810 35976.6 352930585.8 353 0.78 Table4 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-~ _-,w~~- ~ Total --- Total Pumped Cone ~ Pl.!IJI~ Total Total Total Pumped ·cone Cone Tp~I Pumped Total ·!;i~rt~r (g1!,I) , (m~) (1191\) (liters) Total(ug) (gh!fflS) (pounds) (gal) ,(ni~) (ug/L) ,,(liters) Total (ug) Total (gra·ms) (pounds) Q2 2020 136619.7 1.1 1140 517105.6 589500343.5 590 1.30 100713.8 7.23 7230 381201.6 2756087708.6 2756 6.08 Totals Since Q3 2010 7057876.43 336.9 1006106.89 63.4 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW44 TW4-ZZ Total Total Pumped Cone Cone Total Pumped Total Total Pumped Cone Cone Total Pumped Total Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 76916.8 7.30 7300 291130.1 2125249642.4 2125.25 4.69 NA NA NA NA NA NA NA Q4 2010 86872.1 7.10 7100 328810.9 2334557379.4 2334.56 5.15 NA NA NA NA NA NA NA Ql 2011 73360.0 7.00 7000 277667.6 1943673200.0 1943.67 4.29 NA NA NA NA NA NA NA Q2 2011 80334.6 7.00 7000 304066.5 2128465227 .0 2128.47 4.69 NA NA NA NA NA NA NA Q3 2011 97535.0 6.60 6600 369170.0 2436521835.0 2436.52 5.37 NA NA NA NA NA NA NA Q4 2011 109043.5 7.00 7000 412729.6 2889107532.5 2889.11 6.37 NA NA NA NA NA NA NA Ql 2012 101616.8 7.10 7100 384619.6 2730799074.8 2730.80 6.02 NA NA NA NA NA NA NA Q2 2012 87759.1 7.10 7100 332168.2 2358394173.9 2358.39 5.20 NA NA NA NA NA NA NA Q3 2012 80006.0 7.10 7100 302822.7 2150041241.0 2150.04 4.74 NA NA NA NA NA NA NA Q42012 71596.0 7.00 7000 270990.9 1896936020.0 1896.94 4.18 NA NA NA NA NA NA NA Ql 2013 58716.8 7.36 7360 222243.1 1635709127.7 1635.71 3.61 16677.4 58.0 58000.0 63124.0 3661189622.0 3661.2 8.07 Q2 2013 65603.4 6.30 6300 248308.9 1564345874.7 1564.35 3.45 25523.2 50.2 50200.0 96605.3 4849586662.4 4849.6 10.69 Q3 2013 63515.4 7.22 7220 240405.8 1735729796.6 1735.73 3.83 25592.9 29.7 29700.0 96869.1 2877013057.1 2877.0 6.34 Q4 2013 60233.6 7.84 7840 227984.2 1787395939.8 1787.40 3.94 24952.2 45.2 45200.0 94444.1 4268872280.4 4268.9 9.41 Ql 2014 58992.9 7.28 7280 223288.1 1625537560.9 1625.54 3.58 24532.0 54.6 54600.0 92853.6 5069807652.0 5069.8 11.18 Q2 2014 60235.3 5.91 5910 227990.6 1347424508.1 1347.42 2.97 24193.9 47.2 47200.0 91573.9 4322288622.8 4322.3 9.53 Q3 2014 69229.4 5.30 5300 262033.3 1388776378. 7 1388.78 3.06 24610.9 41.5 41500.0 93152.3 3865818644.8 3865.8 8.52 Q42014 64422.6 7.02 7020 243839.5 1711753577.8 1711.75 3.77 23956.9 54.9 54900.0 90676.9 4978159970.9 4978.2 10.97 Ql 2015 36941.3 7.70 7700 139822.8 1076635717 .9 1076.64 2.37 22046.9 69.2 69200.0 83447.5 5774568141.8 5774.6 12.73 Q2 2015 68162.8 6.33 6330 257996.2 1633115933.3 1633.12 3.60 23191.6 47.1 47100.0 87780.2 4134447702.6 4134.4 9.11 Q3 2015 64333.0 6.45 6450 243500.4 1570577612.3 1570.58 3.46 24619.9 64.7 64700.0 93186.3 6029155001.1 6029.2 13.29 Q42015 59235.1 6.27 6270 224204.9 1405764431.4 1405.76 3.10 23657.6 56.1 56100.0 89544.0 5023419297.6 5023.4 11.07 Ql 2016 57274.0 6.71 6710 216782.1 1454607823.9 1454.61 3.21 24517.8 31.1 31100.0 92799.9 2886076050.3 2886.1 6.36 Q2 2016 61378.0 6.56 6560 232315.7 1523991188.8 1523.99 3.36 26506.3 58.4 58400.0 100326.3 5859058577.2 5859.1 12.92 03 2016 50104.2 7.22 7220 189644.4 1369232546.3 1369.23 3.02 22144.1 61.3 61300.0 83815.4 5137885154.1 5137.9 11.33 Q42016 31656.0 6.77 6770 119818.0 811167589.2 811.17 1.79 23646.8 61.5 61500.0 89503.1 5504442987.0 5504.4 12.14 Ql 2017 23526.8 6.87 6870 89048.9 611766204.1 611.77 1.35 24066.2 69.8 69800.0 91090.6 6358121576.6 6358.1 14.02 Q2 2017 23244.9 7.06 7060 87981.9 621152542.3 621.15 1.37 23685.0 70.8 70800.0 89647.7 6347058930.0 6347.1 13.99 Q3 2017 23937.3 6.47 6470 90602.7 586199342.8 586.20 1.29 24583.2 66.1 66100.0 93047.4 6150433933.2 6150.4 13.56 Q42017 22900.6 6.90 6900 86678.8 598083519.9 598.08 1.32 23779.6 80.1 80100.0 90005.8 7209463458.6 7209.5 15.89 Ql 2018 23103.4 6.12 6120 87446.4 535171778.3 535.17 1.18 23982.8 62.3 62300.0 90774.9 5655276145.4 5655.3 12.47 Q2 2018 18137.0 6.34 6340 68648.5 435231775.3 435.23 0.96 23256.6 72.5 72500.0 88026.2 6381901747.5 6381.9 14.07 Q3 2018 15366.0 6.10 6100 58160.3 354777891.0 354.78 0.78 21248.7 55.4 55400.0 80426.3 4455618654.3 4455.6 9.82 Q4 2018 15420.2 6.02 6020 58365.5 351360051.1 351.36 0.77 24171.0 75.7 75700.0 91487.2 6925583689.5 6925.6 15.27 Ql 2019 16655.0 7.26 7260 63039.2 457664410.5 457.66 1.01 26149.9 71.9 71900.0 98977.4 7116473010.9 7116.5 15.69 Q2 2019 14311.9 10.4 10400 54170.5 563373631.6 563.37 1.24 23073.1 83.9 83900.0 87331.7 7327128245.7 7327.1 16.15 Q3 2019 14520.0 6.32 6320 54958.2 347335824.0 347.34 0.77 24711.7 72.5 72500.0 93533.8 6781199376.3 6781.2 14.95 Q4 2019 14399.8 6.52 6520 54503.2 355361144.4 355.36 0.78 24052.S 59.9 59900.0 91038.7 5453218878.8 5453.2 12.02 Ql 2020 14439.2 4.58 4580 54652.4 250307863.8 250.31 0.55 24746.1 57.7 57700.0 93664.0 5404412136.S 5404.4 11.91 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW~ TW4-22_ Total Tolar Pum~ Cone Cone TotalPum~ Tomi Total Pum~ CGi1C Cone T~I P'l,lmpej;i' Total Total Ouar!eJ _(gal) (m.gll.) (ugl!..) (lite!'§) To.Tai {ug) (gronftl (ppunds) (9-ril) {l)ig/1:,,}' (ug/L) {l~,iri.;)_. it;~l(~} (gram}) ffi,O!J!'WS) Q2 2020 15347.0 7.26 7260 58088.4 421721747.7 421.72 0.93 25295.3 605 60500.0 95742.7 5792433985.3 5792.4 12.77 Totals Since Q3 2010 2050382.80 117.1 717172.1 356.3 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-24 TW4-25 Totar Total Pumped Cone Cone Total Pumped Total Total Total Pumped Cone Cone Pumped Total Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q42012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2013 144842.6 35.9 35900 548229.2 19681429751.9 19681.4 43.39 99369.9 9.00 9000 376115.1 3385035643.5 3385.0 7.46 Q2 2013 187509.3 23.7 23700 709722.7 16820428001.9 16820.4 37.08 147310.4 5.24 5240 557569.9 2921666087 .4 2921.7 6.44 Q3 2013 267703.5 32.6 32600 1013257.7 33032202568.5 33032.2 72.82 145840.9 5.69 5690 552007.8 3140924419.0 3140.9 6.92 Q4 2013 260555.3 34.6 34600 986201.8 34122582643.3 34122.6 75.23 126576.5 6.10 6100 479092.1 2922461520.3 2922.5 6.44 Ql 2014 229063.9 31.6 31600 867006.9 27397416823.4 27397.4 60.40 129979.2 2.16 2160 491971.3 1062657947.5 1062.7 2.34 Q2 2014 216984.1 35.0 35000 821284.8 28744968647.5 28745.0 63.37 124829.8 1.21 1210 472480.8 571701759.5 571.7 1.26 Q3 2014 213652.5 31.5 31500 808674.7 25473253443.8 25473.3 56.16 119663.9 1.60 1600 452927.9 724684578.4 724.7 1.60 Q4 2014 178468.7 35.7 35700 675504.0 24115493853.2 24115.5 53.17 107416.1 1.03 1030 406569.9 418767036. 7 418.8 0.92 Ql 2015 92449.3 34.6 34600 349920.6 12107252777.3 12107.3 26.69 71452.4 14.40 14400 270447.3 3894441609.6 3894.4 8.59 Q2 2015 62664.2 31.8 31800 237184.0 7542451104.6 7542.5 16.63 91985.3 1.14 1140 348164.4 396907371.0 396.9 0.88 Q3 2015 66313.2 25.3 25300 250995.5 6350185188.6 6350.2 14.00 124137.1 1.63 1630 469858.9 765870045.3 765.9 1.69 Q4 2015 107799.1 29.6 29600 408019.6 12077379967.6 12077.4 26.63 116420.1 1.78 1780 440650.1 78435 7139. 7 784.4 1.73 Ql 2016 100063.2 29.1 29100 378739.2 11021311069.2 11021.3 24.30 115483.2 0.84 837 437103.9 365855974.3 365.9 0.81 Q2 2016 65233.6 24.2 24200 246909.2 5975202059.2 5975.2 13.17 125606.0 0.96 959 475418.7 455926542.9 455.9 1.01 Q3 2016 51765.8 34.4 34400 195933.6 6740114223.2 6740.1 14.86 104983.6 1.78 1780 397362.9 707306008.3 707.3 1.56 Q4 2016 99522.5 31.9 31900 376692.7 12016495933.8 12016.5 26.49 98681.2 1.24 1240 373508.3 463150344.1 463.2 1.02 Ql 2017 99117.4 41.3 41300 375159.4 15494081526.7 15494.1 34.16 161.2 17.0 17000 610.1 10372414.0 10.4 0.02 Q2 2017 52808.7 39.9 39900 199880.9 7975249087.1 7975.2 17.58 101617.2 0.976 976 384621.1 375390195.6 375.4 0.83 Q3 2017 55574.6 40.0 40000 210349.9 8413994440.0 8414.0 18.55 124138.4 1.23 1230 469863.8 577932528.1 577.9 1.27 Q4 2017 106021.4 31.7 31700 401291.0 12720924668.3 12720.9 28.04 116731.9 1.29 1290 441830.2 569961011.5 570.0 1.26 Ql 2018 96900.2 44.9 44900 366767.3 16467849839.3 16467.8 36.31 116991.7 2.23 2230 442813.6 987 4 7 4293 .4 987.5 2.18 Q2 2018 53117.9 33.6 33600 201051.3 6755322050.4 6755.3 14.89 117758.3 1.14 1140 445715.2 508115288.7 508.1 1.12 Q3 2018 53142.6 33.8 33800 201144.8 6798693525.1 6798.7 14.99 111657.S 0.810 810 422623.6 342325146.4 342.3 0.75 Q42018 101606.4 38.4 38400 384580.2 14767880601.6 14767.9 32.56 114458.2 0.634 634 433224.3 274664198.0 274.7 0.61 Ql 2019 97701.0 39.3 39300 369798.4 14533077063.0 14533.1 32.04 90789.S 0.639 639 343638.1 219584725.6 219.6 0.48 Q2 2019 53197.3 33.2 33200 201351.9 6684881625.8 6684.9 14.74 88302.0 0.821 821 334223.1 274397140.S 274.4 0.60 Q3 2019 54445.7 36.4 36400 206077.0 7501201871.8 7501.2 16.54 87609.5 0.548 548 331602.0 181717872.7 181.7 0.40 Q42019 102211.0 33.8 33800 386868.7 13076162421.7 13076.2 28.83 85928.S 0.841 841 325239.5 273526407.8 273.S 0.60 Ql 2020 86344.4 37.1 37100 326813.S 12124780044.9 12124.8 26.73 85049.5 0.607 607 321912.2 195400732.1 195.4 0.43 Table4 Quarterly Calculation or Nitrate Removed and Total Volume or Water Pumped l'W~:24 TW4-25 - Tci!jlJ roffil f'umpee Coll!a. epnc 10~1 P-urilped T@tal Total 'fo,al P:Umpoo Cof~ Cone P{!fflfled Total Tota.I QuQrtllf' fylf11) (in~ -"(u~/1.), !lit~f-l>) Ttil',JI (u_@ {9~§) (Pounds) (gal) (m"g/L) (ug/l) (lilel"f!) 1e!l:!l i,i;ig), (9,l'aJ!!li') (J!Ounds) Q2 2020 57634.7 41.7 41700 218147.3 9096744057.2 9096.7 20.05 90767.9 0.851 851 343556.6 292366679.4 292.4 0.64 Totals Since Q3 2010 3414414.2 960.4 3181696.88 61.9 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped lWN-02 TW4-01 Total Total Pumped Cone Cone Total Pumped Total Total Pumped Cone Cone Total Pumped Total Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2013 31009.4 57.3 57300 117370.6 6725334176.7 6725.3 14.83 NA NA NA NA NA NA NA Q2 2013 49579.3 57.7 57700 187657.7 10827846433.9 10827.8 23.87 NA NA NA NA NA NA NA Q3 2013 50036.S 80.0 80000 189388.2 15151052200.0 15151.1 33.40 NA NA NA NA NA NA NA Q4 2013 49979.9 111.0 111000 189173.9 20998305286.S 20998.3 46.29 NA NA NA NA NA NA NA Ql 2014 48320.4 42.6 42600 182892.7 7791229616.4 7791.2 17.18 NA NA NA NA NA NA NA Q2 2014 47611.9 44.7 44700 180211.0 8055433555.1 8055.4 17.76 NA NA NA NA NA NA NA Q3 2014 46927.2 42.0 42000 177619.S 7460016984.0 7460.0 16.45 NA NA NA NA NA NA NA Q4 2014 47585.6 70.6 70600 180111.5 12715871617 .6 12715.9 28.03 NA NA NA NA NA NA NA Ql 2015 47262.2 48.6 48600 178887.4 8693928952.2 8693.9 19.17 24569.2 7.06 7060 92994.4 656540619.3 656.S 1.45 Q2 2015 48497.3 52.8 52800 183562.3 9692088410.4 9692.1 21.37 23989.9 6.07 6070 90801.8 551166753.0 551.2 1.22 Q3 2015 48617.4 49.7 49700 184016.9 9145637892.3 9145.6 20.16 23652.0 6.3 6280 89522.8 562203309.6 562.2 1.2 Q4 2015 46754.1 44.9 44900 176964.3 7945695655.7 7945.7 17.52 20764.3 1.55 1550 78592.9 121818957.0 121.8 0.27 Ql 2016 47670.2 86.3 86300 180431.7 15571256314.1 15571.3 34.33 19255.6 0.15 148 72882.4 10786602.0 10.8 0.02 Q2 2016 50783.0 45.4 45400 192213.7 8726499937.0 8726.S 19.24 19588.2 0.14 138 74141.3 10231504.S 10.2 0.02 Q3 2016 42329.6 35.3 35300 160217.S 5655679020.8 5655.7 12.47 15613.S 5.49 5490 59097.1 324443065.3 324.4 0.72 Q4 2016 44640.6 32.6 32600 168964.7 5508248274.6 5508.2 12.14 16756.8 0.75 746 63424.S 47314668.0 47.3 0.10 Ql 2017 45283.2 27.4 27400 171396.9 4696275388.8 4696.3 10.35 16931.8 4.44 4440 64086.9 284545671.7 284.5 0.63 Q2 2017 42550.6 25.0 25000 161054.0 4026350525.0 4026.4 8.88 18200.2 5.74 5740 68887.8 395415725.2 395.4 0.87 Q3 2017 46668.9 23.9 23900 176641.8 4221738697.4 4221.7 9.31 17413.6 5.04 5040 65910.S 332188799.0 332.2 0.73 Q4 2017 38964.7 31.9 31900 147481.4 4704656325.1 4704.7 10.37 14089.8 5.78 5780 53329.9 308246781.S 308.2 0.68 Ql 2018 43341.0 19.6 19600 164045.7 3215295426.0 3215.3 7.09 12505.7 4.84 4840 47334.1 229096920.6 229.1 0.51 Q2 2018 43697.0 19.8 19800 165393.1 3274784271.0 3274.8 7.22 10814.8 4.38 4380 40934.0 179290998.8 179.3 0.40 Q3 2018 41776.0 18.6 18600 158122.2 2941072176.0 2941.1 6.48 9727.3 4.30 4300 36817.8 158316671.2 158.3 0.35 Q4 2018 38545.8 19.6 19600 145895.9 2859558718.8 2859.6 6.30 9836.7 4.57 4570 37231.9 170149826.4 170.1 0.38 Ql 2019 44752.8 19.0 19000 169389.3 3218397612.0 3218.4 7.10 10603.6 4.51 4510 40134.6 181007163.3 181.0 0.40 Q2 2019 43432.2 45.1 45100 164390.9 7414028552.7 7414.0 16.35 9393.9 1.43 1430 35555.9 50844953.4 50.8 0.11 Q3 2019 41377.S 23.2 23200 156613.8 3633441030.0 3633.4 8.01 9734.1 1.65 1650 36843.6 60791888.0 60.8 0.13 Q4 2019 34011.4 18.2 18200 128733.1 2342943311.8 2342.9 5.17 9184.3 3.91 3910 34762.6 135921670.2 135.9 0.30 Ql 2020 32230.0 16.S 16500 121990.6 2012844075.0 2012.8 4.44 9796.7 4.67 4670 37080.5 173165979.4 173.2 0.38 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped lWN:(!2 " TW~l -T'otat --' -Total .. " Toial Pumpe&l . flumfi!e<i Gone C'911'¢ T(l~1Pum)1!!ld TQtal To1nl flurilped ~9\19 eonc Total ietal Qli3rt!jr (a&I) (mgllj (ugly} (lite11,) T01al (.u_g) (grams) (pounds) (gal) (mg/L) (ug/L) <•a~rs> I Total (ug) (grams) (ppunds) Q2 2020 30078.9 16.1 16100 113848.6 1832963047.7 1833.0 4.04 9600.2 0.443 443 36336.8 I 16097183.4 16.1 0.04 Totals Since Q3 2010 1314314.6 465.3 332022.20 10.9 Table 4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-02 TW4-ll Total Total Total Pumped Cone Cone Total Pumped Total Total Pumped Cone Cone Pumped Total Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q42012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2015 24156.7 5.32 5320 91433.1 486424142.5 486.4 1.07 9898.7 8.72 8720 37466.6 326708573.2 326.7 0.72 Q2 2015 22029.9 4.30 4300 83383.2 358547637.5 358.5 0.79 5243.3 8.48 8480 19845.9 168293151.4 168.3 0.37 Q3 2015 21586.9 3.8 3760 81706.4 307216126.0 307.2 0.7 3584.4 9.6 9610 13567.0 130378427.9 130.4 0.3 Q4 2015 21769.8 5.18 5180 82398.7 426825229.7 426.8 0.94 4110.3 7.50 7500 15557.5 116681141.3 116.7 0.26 Ql 2016 20944.6 5.30 5300 79275.3 420159148.3 420.2 0.93 3676.2 7.13 7130 13914.4 99209793.2 99.2 0.22 Q2 2016 20624.0 6.67 6670 78061.8 520672472.8 520.7 1.15 3760.4 7.81 7810 14233.1 111160620.3 111.2 0.25 Q3 2016 17487.4 4.07 4070 66189.8 269392522.6 269.4 0.59 2953.8 8.83 8830 11180.1 98720574.4 98.7 0.22 Q4 2016 19740.6 6.07 6070 74718.2 453539298.0 453.5 1.00 3050.2 8.92 8920 11545.0 102981462.4 103.0 0.23 Ql 2017 19869.7 4.74 4740 75206.8 356480300.7 356.5 0.79 2984.2 8.12 8120 11295.2 91716999.6 91.7 0.20 Q2 2017 18716.7 4.90 4900 70842.7 347129276.6 347.1 0.77 2845.9 7.92 7920 10771.7 85312113.5 85.3 0.19 Q3 2017 19338.8 5.08 5080 73197.4 371842578.6 371.8 0.82 2830.0 7.78 7780 10711.6 83335859.0 83.3 0.18 Q4 2017 17327.6 3.28 3280 65585.0 215118688.5 215.1 0.47 2612.7 7.79 7790 9889.1 77035851.4 77.0 0.17 Ql 2018 16232.3 2.94 2940 61439.3 180631411.2 180.6 0.40 2571.0 7.89 7890 9731.2 76779444.2 76.8 0.17 Q2 2018 16051.4 3.50 3500 60754.5 212640921.5 212.6 0.47 2513.5 7.51 7510 9513.6 71447117.2 71.4 0.16 Q3 2018 14927.2 4.83 4830 56499.5 272892353.2 272.9 0.60 2170.2 7.15 7150 8214.2 58731580.1 58.7 0.13 Q4 2018 15464.1 3.52 3520 58531.6 206031297.1 206.0 0.45 2379.5 6.85 6850 9006.4 61693891.4 61.7 0.14 Ql 2019 16169.9 3.92 3920 61203.1 239916040.3 239.9 0.53 2342.4 7.50 7500 8866.0 66494880.0 66.5 0.15 Q2 2019 13893.7 4.38 4380 52587.7 230333926.7 230.3 0.51 2195.1 8.30 8300 8308.5 68960164.1 69.0 0.15 Q3 2019 14106.9 4.79 4790 53394.6 255760213.0 255.8 0.56 2046.0 7.15 7150 7744.1 55370386.5 55.4 0.12 Q4 2019 14220.9 3.40 3400 53826.1 183008762.1 183.0 0.40 1983.9 7.14 7140 7509.1 53614699.1 53.6 0.12 Ql 2020 13162.1 6.07 6070 49818.5 302398589.4 302.4 0.67 1947.4 7.07 7070 7370.9 52112326.6 52.1 0.11 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW:4-()2 TW4-ll Total Total Total Pumped Cone ea:ne 'ra:m1i;ium~ Total To~I Bwm~ Cone Cone · Pumped Total Total :Quarter (gal) (mgll.:> (1:!.Qll,l ~ 1•ittof.@ -0 Total (1,19) (gr11m_s) (ppUnd!I) (9!1) (njg/l.,) (ug/1.) (liter§) Total (ug) (grams) '(pou~s) Q22020 14155.6 3.62 3620 53578.9 193955784.5 194.0 0.43 2003.9 7.56 7560 7584.8 57340796.9 57.3 0.13 Totals Since Q3 2010 391976.80 15.0 69703.00 4.7 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-21 TW4-37 'Total Total Pumped Cone Cone Total Pumped Total Total Pumped Cone Cone Total Pumped Total Total Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Q3 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q42011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q42013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2015 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2015 30743.7 13.1 13100 116364.9 1524380249.0 1524.4 3.4 29206.0 35.2 35200 110544.7 3891173792.0 3891.2 8.6 Q3 2015 125285.4 14.7 14700 474205.2 6970817013.3 6970.8 15.4 118063.9 32.4 32400 446871.9 14478648312.6 14478.6 31.9 Q4 2015 134774.9 14.30 14300 510123.0 7294758850.0 7294.8 16.08 111737.5 34.60 34600 422926.4 14633254737.5 14633.3 32.26 Ql 2016 125513.3 14.60 14600 475067.8 6935990471.3 6936.0 15.29 111591.0 28.40 28400 422371.9 11995362954.0 11995.4 26.45 Q2 2016 132248.7 13.10 13100 500561.3 6557353416.5 6557.4 14.46 119241.2 27.90 27900 451327.9 12592049581.8 12592.0 27.76 Q3 2016 110381.9 16.50 16500 417795.5 6893625609.8 6893.6 15.20 98377.6 33.40 33400 372359.2 12436797814.4 12436.8 27.42 Q4 2016 130311.3 13.50 13500 493228.3 6658581651.8 6658.6 14.68 101949.1 26.10 26100 385877.3 10071398665.4 10071.4 22.20 Ql 2017 54333.5 17.70 17700 205652.3 3640045665.8 3640.0 8.02 97071.7 32.30 32300 367416.4 11867549219.4 11867.5 26.16 Q2 2017 60969.7 9.53 9530 230770.3 2199241097.2 2199.2 4.85 93191.3 31.20 31200 352729.1 11005146999.6 11005.1 24.26 Q3 2017 120116.2 18.2 18200 454639.8 8274444669.4 8274.4 18.24 81749.3 30.5 30500 309421.1 9437343565.3 9437.3 20.81 Q4 2017 126492.5 16.9 16900 478774.1 8091282501.3 8091.3 17.84 87529.6 30.6 30600 331299.5 10137765801.6 10137.8 22.35 Ql 2018 117832.0 15.8 15800 445994.1 7046707096.0 7046.7 15.54 84769.3 30.0 30000 320851.8 9625554015.0 9625.6 21.22 Q2 2018 116681.0 14.1 14100 441637.6 6227089948.5 6227.1 13.73 83653.1 28.6 28600 316627.0 9055531728.1 9055.5 19.96 Q3 2018 110001.4 0.236 236 416355.3 98259850.6 98.3 0.22 77457.8 25.4 25400 293177.8 7446715434.2 7446.7 16.42 Q42018 121686.3 15.2 15200 460582.6 7000856211.6 7000.9 15.43 76271.4 27.3 27300 288687.2 7881161897.7 7881.2 17.38 Ql 2019 123264.1 8.99 8990 466554.5 4194325339.8 4194.3 9.25 77591.4 30.1 30100 293683.4 8839871814.9 8839.9 19.49 Q2 2019 106893.6 17.5 17500 404592.3 7080364830.0 7080.4 15.61 64950.1 31.2 31200 245836.1 7670087209.2 7670.1 16.91 Q3 2019 108132.9 14.7 14700 409283.0 6016460489.6 6016.5 13.26 67572.0 25.8 25800 255760.0 6598608516.0 6598.6 14.55 Q42019 116167.6 5.73 5730 439694.2 2519447632.8 2519.4 5.55 66732.4 25.5 25500 252582.1 6440844417.0 6440.8 14.20 Ql 2020 106622.0 8.93 8930 403564.3 3603829269.1 3603.8 7.95 65554.2 28.3 28300 248122.6 7021870910.1 7021.9 15.48 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4,-21 'IW~37 ,otal Total Pumpecl eonc Co,nc Total Pumped Tob!I Totaj Pumped ·Coi:ic Cone Total Purrfpecl Tof.11 Tot.iii Quarter (~I) (mgil.) (~) ~liters) TQta,1 (ug) (grams) ,(pounds) , (gal) (mgfl) cu'g11.1 !;ll)eis) Total (ug) Cs1rari\s) '(poun10} Q2 2020 110999.1 15.4 15400 420131.7 6470028288.6 6470.0 14.26 65163.8 28.3 28300 246645.0 6980053018.9 6980.1 15.39 Totals Since Q3 2010 2289451.1 254.2 1779423.7 441.2 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4-39 TW4-40 Total Total Total Total Pumped Cone Cone Pumped Total Total Pumped Pumped Total Quarter (gal) (mg/l) (ug/L) (liters) Total (ug) (grams) (pounds) (gal) Cone(mg/L) Cone (ug/L) (liters) Total (ug) Total (grams) (pounds) Q3 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2010 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2011 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2012 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q42013 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2014 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2015 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2015 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2015 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2015 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Ql 2016 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q2 2016 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q3 2016 NA NA NA NA NA NA NA NA NA NA NA NA NA NA Q4 2016 3589.3 20.70 20700 13585.5 281219860.4 281.2 0.62 NA NA NA NA NA NA NA Ql 2017 103117.8 6.44 6440 390300.9 2513537622.1 2513.5 5.54 NA NA NA NA NA NA NA Q2 2017 41313.0 6.25 6250 156369.7 977310656.3 977.3 2.15 NA NA NA NA NA NA NA Q3 2017 34546.3 7.74 7740 130757.7 1012064950.2 1012.1 2.23 NA NA NA NA NA NA NA Q42017 68180.2 2.65 2650 258062.1 683864451.1 683.9 1.51 NA NA NA NA NA NA NA Ql 2018 59262.2 3.33 3330 224307.4 7 46943 731.9 746.9 1.65 NA NA NA NA NA NA NA Q2 2018 34259.8 4.84 4840 129673.3 627618980.1 627.6 1.38 NA NA NA NA NA NA NA Q3 2018 33473.4 6.05 6050 126696.8 766515755.0 766.5 1.69 NA NA NA NA NA NA NA Q42018 37003.6 6.39 6390 140058.6 894974620.1 895.0 1.97 NA NA NA NA NA NA NA Ql 2019 49116.9 2.08 2080 185907.5 386687530.3 386.7 0.85 NA NA NA NA NA NA NA Q2 2019 34285.7 8.45 8450 129771.4 1096568114.5 1096.6 2.42 81762.8 3.55 3550.0 309472.2 1098626302.9 1098.6 2.4 Q3 2019 36976.2 1.75 1750 139954.9 244921104.8 244.9 0.54 116414.2 3.39 3390.0 440627.7 1493 728062.3 1493.7 3.3 Q4 2019 51808.6 0.948 948 196095.6 185898582.3 185.9 0.41 108281.9 2.89 2890.0 409847.0 1184457696.0 1184.5 2.6 Ql 2020 43169.3 0.792 792 163395.8 129409474.0 129.4 0.29 102021.5 2.98 2980.0 386151.4 1150731217.7 1150.7 2.5 Table4 Quarterly Cakulation of Nitrate Removed and Total Volume of Water Pumped TW4--39,. w.w- Total Tt,;tfil I -----nim1 Total Pum~ CQn.c. ~o.n_c Pu~~ ,:01~ T<?"~I P!;i~r;!fl.d P~m~ tQt~J ~ _.. GIU!l~r (gal) '(m~), (µgll) tli~) l'Q.l'ffl (ll,€t) (g_rams} (pounds) (g:._{} Conc{mgiL_J C,.o,lic (1,/.KLJ (liter;s) T~I fllg) "rot.al ('g1:.a.rti~} (pound.s) Q2 2020 37352.7 5.010 5010 141380.o I 108313647.2 708.3 1.56 100757.1 2.91 2910.0 381365.7 1109774294.8 1109.8 2.4 Totals Since Q3 2010 667455.00 24.8 13.3 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped . TW4-41 ·Total Removed Total Pumped Cone Cone Pumped Total Total by All Quarter (gal) (mg/L) (ug/L) (liters) Total (ug) (grams) (pounds) Wells Q3 2010 NA NA NA NA NA NA NA 15.69 Q4 2010 NA NA NA NA NA NA NA 27.97 Ql 2011 NA NA NA NA NA NA NA 73.30 Q2 2011 NA NA NA NA NA NA NA 27.01 Q3 2011 NA NA NA NA NA NA NA 16.82 Q4 2011 NA NA NA NA NA NA NA 19.71 Ql 2012 NA NA NA NA NA NA NA 15.86 Q2 2012 NA NA NA NA NA NA NA 15.03 Q3 2012 NA NA NA NA NA NA NA 14.67 Q4 2012 NA NA NA NA NA NA NA 14.92 Ql 2013 NA NA NA NA NA NA NA 95.73 Q2 2013 NA NA NA NA NA NA NA 91.71 Q3 2013 NA NA NA NA NA NA NA 176.53 Q4 2013 NA NA NA NA NA NA NA 162.07 Ql 2014 NA NA NA NA NA NA NA 103.14 Q2 2014 NA NA NA NA NA NA NA 101.87 Q3 2014 NA NA NA NA NA NA NA 92.99 Q4 2014 NA NA NA NA NA NA NA 108.57 Ql 2015 NA NA NA NA NA NA NA 82.61 Q2 2015 NA NA NA NA NA NA NA 68.86 Q3 2015 NA NA NA NA NA NA NA 118.63 Q4 2015 NA NA NA NA NA NA NA 124.50 Ql 2016 NA NA NA NA NA NA NA 132.55 Q2 2016 NA NA NA NA NA NA NA 99.98 Q3 2016 NA NA NA NA NA NA NA 101.12 Q4 2016 NA NA NA NA NA NA NA 106.06 Ql 2017 NA NA NA NA NA NA NA 116.19 Q2 2017 NA NA NA NA NA NA NA 80.12 Q3 2017 NA NA NA NA NA NA NA 93.37 Q4 2017 NA NA NA NA NA NA NA 106.21 Ql 2018 NA NA NA NA NA NA NA 111.99 Q2 2018 73711.2 6.54 6540 278996.9 1824639673.7 1824.6 4.02 84.14 Q3 2018 44981.6 6.13 6130 170255.2 1043664404.2 1043.7 2.30 61.86 Q42018 35431.5 6.02 6020 134108.2 807331529.6 807.3 1.78 98.49 Ql 2019 31903.6 6.71 6710 120755.1 810266895.5 810.3 1.79 101.08 Q2 2019 25146.5 6.00 6000 95179.5 571077015.0 571.1 1.26 101.72 Q3 2019 24045.6 6.22 6220 91012.6 566098347.1 566.1 1.25 80.19 Q4 2019 21186.4 6.11 6110 80190.5 489964101.6 490.0 1.08 76.97 Ql 2020 17289.9 6.12 6120 65442.3 400506701.6 400.5 0.88 86.86 Table4 Quarterly Calculation of Nitrate Removed and Total Volume of Water Pumped TW4c41 Total Removed Total Pumped Cone ,C.onc ~umped 10.tal Toil!I by All Quarter (gal)' (mg/L) (ug/1,.) (liters) Total (ug) ,(grams) (pounds) Wells Q2 2020 17294.9 6.78 6780 65461.1 443826399.0 443.8 0.98 85.95 Totals Since Q3 2010 290991.14 15.3 3293.02 Table 5 Nitrate Date Over Time for MW-30, MW-31, MW-5, and MW-11 Date MW-30 Q2 2010 Q3 2010 Q4 2010 Ql 2011 Q2 2011 Q3 2011 Q4 2011 QI 2012 Q2 2012 Q3 2012 Q4 2012 QI 2013 Q2 2013 Q3 2013 Q4 2013 QI 2014 Q2 2014 Q3 2014 Q4 2014 QI 2015 Q2 2015 Q3 2015 Q4 2015 QI 2016 Q2 2016 Q3 2016 Q4 2016 QI 2017 Q2 2017 Q3 2017 Q4 2017 QI 2018 Q2 2018 Q3 2018 Q4 2018 Ql 2019 Q2 2019 Q3 2019 Q4 2019 QI 2020 Q2 2020 ND= Not detected NS = Not Sampled 15.8 15 16 16 17 16 16 17 16 17 18.5 21.4 18.8 17.6 19.5 18.4 19.4 16.8 16.2 14.9 17.0 17.9 16.3 20.0 17.3 18.0 17.2 17.4 17.5 19.2 17.4 17.6 17.3 18.0 17.3 17.9 18.5 19.3 18.2 16.4 18.1 MW-31 22.5 21 20 21 22 21 21 21 20 21 23.6 19.3 23.8 21.7 23.9 20.6 23.1 18.9 20.9 18.7 19.0 19.9 18.4 18.8 18.6 19.7 18.8 21.1 18.3 19.5 19.2 18.8 19.0 20.1 18.3 19.0 19.7 19.8 19.8 17.5 18.8 MW-5 MW-11 ND ND NS ND 0.2 ND NS ND 0.2 ND NS ND 0.2 ND NS ND 0.1 ND NS ND ND ND NS ND ND ND NS ND 0.279 ND NS ND ND ND NS ND 0.21 ND NS ND 0.142 ND NS ND 0.118 ND NS ND 0.156 0.117 NS ND 0.241 ND NS ND 0.133 ND NS ND 0.337 ND NS ND 0.216 ND NS ND 0.309 ND NS ND 0.260 ND NS 0.558 0.235 0.160 NS 0.308 0.142 0.297 TABLE 6 Slug Test Results (Using KGS Solution and Automatically Logged Data) Well K lcm/s) MW-30 1.0E-04 MW-31 7.1 E-05 TW4-22 1.3E-04 TW4-24 1.6E-04 TW4-25 5.BE-05 TWN-2 1.5E-05 TWN-3 8.6E-06 Average 1 Average2 Average3 Average 4 Notes: Average 1 = arithemetic average of all wells Average 2 = geometric average of all wells K lft/dav) 0.28 0.20 0.36 0.45 0.16 0.042 0.024 0.22 0.15 0.32 0.31 Average 3 = arithemetic average of MW-30, MW-31, TW4-22, and TW4-24 Average 4 = geometric average of MW-30, MW-31, TW4-22, and TW4-24 cm/s = centimeters per second ft/day= feet per day K = hydraulic conductivity KGS = KGS Unconfined Slug Test Solution in Aqtesolve TM. S:\Environmental\UT\WhiteMesaMill\Required Reports\Nitrate Quarterly Report\2020 02\FlowCalcs -Tables 6-7-8.xls: Table 6 Well TW4-22 TW4-24 Notes: ft= feet TABLE 7 Pre-Pumping Saturated Thicknesses Depth to Depth to Water Saturated Thickness Brushy Basin Fourth Quarter, 2012 Above Brushy Basin (ft) (ft) (ft) 112 53 58 110 55 55 S:\Environmental\UnWhiteMesaMill\Required Reports\Nitrate Quarterly Report\2020 02\FlowCalcs -Tables 6-7-8.xls: Table 7 TABLE 8 Pre-Pumping Hydraulic Gradients and Flow Calculations Pathline Boundaries TW4-25 to MW-31 TWN-2 to MW-30 Notes: ft= feet ft/ft = feet per foot gpm = gallons per minute Path Length (ft) 2060 2450 Head Change Hydraulic Gradient (ft) (ft/ft) 48 0.023 67 0.027 average 0.025 1 min flow (gpm) 1.31 2 max flow (gpm) 2.79 1 assumes width = 1,200 ft; saturated thickness = 56 ft; K = 0.15 ft/day; and gradient = 0.025 fVft 2 assumes width = 1,200 ft; saturated thickness = 56 ft; K = 0.32 ft/day; and gradient = 0.025 ft/ft S:\Environmental\UT\WhiteMesaMill\Required Reports\Nitrate Quarterly Report\2020 Q2\FlowCalcs -Tables 6-7-8.xls: Table 8 Table 9 *Recalculated Background Flow Background *Recalculated Flow Background Flow laom) laom) minimum 1.31 0.79 maximum 2.79 1.67 * recalculated based on reduced widlife pond recharge as presented in the third quarter, 2015 Nitrate Monitoring Report gpm = gallons per minute INDEX OF TABS Tab A Site Plan and Perched Well Locations White Mesa Site Tab B Order of Sampling and Field Data Worksheets Tab C Kriged Current Quarter Groundwater Contour Map, Capture Zone Map, Capture Zone Details Map, and Weekly, Monthly and Quarterly Depth to Water Data Tab D Kriged Previous Quarter Groundwater Contour Map Tab E Hydrographs of Groundwater Elevations over Time for Nitrate Monitoring Wells Tab F Depths to Groundwater and Elevations over Time for Nitrate Monitoring Wells Tab G Laboratory Analytical Reports Tab H Quality Assurance and Data Validation Tables H-1 Field Data QA/QC Evaluation H-2 Holding Time Evaluation H-3 Analytical Method Check H-4 Reporting Limit Evaluation H-5 QA/QC Evaluation for Sample Duplicates H-6 QC Control Limits for Analyses and Blanks H-7 Receipt Temperature Evaluation H-8 Rinsate Evaluation Tab I Kriged Current Quarter Isoconcentration Maps Tab J Analyte Concentration Data over Time Tab K Concentration Trend Graphs Tab L CSV Transmittal Letter Tab M Residual Mass Estimate Analysis Figure Tab A Site Plan and Perched Well Locations White Mesa Site MW-24A perched monitoring well installed • December 2019 TW4-42 ¢ temporary perched monitoring well installed April 2019 TW4-40 perched chloroform pumping well E9 installed February 2018 TW4-19 perched chloroform or E9 nitrate pumping well MW-38 -¢-perched monitoring well installed February 2018 MW-5 • perched monitoring well TW4-12 0 temporary perched monitoring well TWN-7 temporary perched nitrate monitoring ~ well PIEZ-1 perched piezometer Q RUIN SPRING o seep or spring HYDRO GEO CHEM, INC. WHITE MESA SITE PLAN SHOWING LOCATIONS OF PERCHED WELLS AND PIEZOMETERS APPROVED DATE REFERENCE H:/718000/aug19/Uwelloc1219.srf FIGURE A-1 TabB Order of Sampling and Field Data Worksheets Nitrate Samples Nitrate Mg/L Previous Name Qrt. Date/Purge sample TWN-18 0.224 TWN-04 1.89 TWN-01 2.24 TWN-07 14.20 TWN-02 16.5 TWN-03 19.4 Duplicate of "f w iv -D '"I Rinsate DI Sample Tw/J -C.,O Piez-01 7.12 Piez-0 2 Piez-03A 0.74 10.5 5/;;J.D/:J..h 0 'l3i-. S/2-0/10 o~ ILf ,; I Z.0/'1.D o .::i so Slz.1 I :w 1015 s!zo/~ 10-;o T;,./1..) /;J..O JO~ 5/:W/)..D O'll'-1 5/:J..O/;;..D ,~~o ,;,./2.0/2,0 1;2.:-t D 5 I ;..o l:i.." l~ 5 /).1) l:i.o 130" Nitrate Order 2nd Quarter 2020 Depth Total Depth 145 125.7 112.5 105 96 96 Rlnsate Samples Name Date Sample lWN-1sR I s 120/:2.0 I oa 1::, lWN·4R lWN-lR lWN-7R TWN-3R lWN-2R Samplers: //c1,1111e:r 1-JolJ,Jl?J Dee.,., Lj t'Ytc:...~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID PIEZ-01 Sampling Pro_gram Nitrate Quarterly Field Sample ID PIEZ-01 05202020 Sampling Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 12:35 Sample Date & Time 5/20/2020 12:40 [sampler TH/DL Purging Equipment Bailer Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 19 Purging Method 2 Casings Previous Well Sampled PIEZ-02 Casing Volume (gal) 1.66 Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) 107.50 pH Buffer 4.0 4.0 Well Casing Diameter (in) 1 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 66.84 Conductivity Dissolved Date/Time Gallons Purged (um hos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/20/2020 12:39 2300 6.55 15.28 351 5.6 63.0 [volume of water_l)lJrged 0 Pumping_ Rate Calculations Flow Rate (Q = S/60) () Time to evacuate 2 Casing Volumes () [ Final Depth to Water (feet) 67.85 Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Anal}'t_ical Laborato_ry AWSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y Comments: j Arrived on site at 1233. Samples bailed and collected at 1240. 'Nater was murky. Left site at 1246. Signature of Field Technician ~~~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID PIEZ-02 Samelin_g Program Nitrate Quarterly Field Sample ID PIEZ-02 05202020 Sampling Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 12:20 Sample Date & Time 5/20/2020 12:25 [sampler TH/DL Purging Equipment Bailer Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 18 Purging Method 2 Casings Previous Well Sampled TWN-03 Casing Volume (gal) 2.26 Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) 100.00 pH Buffer 4.0 4.0 Well Casing Diameter (in) 1 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 44.82 Conductivity Dissolved Date!Time Gallons Purged (umhos/cm) pH (pH Units) Temp (deg C) Redox(mV) Turbidity (NTU) Oxygen(%) Before/After 5/20/2020 12:22 853.1 6.74 15.35 335 0.8 23.S Pumping Rate Calculations [volume of water purged O Flow Rate (Q = S/60) () Time to evacuate 2 Casing Volumes 0 [Final Depth to Water (feet) 45.90 Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Anal~ical Laboratory AWSL Anal~ical Samples Information Sample Container Preservative Type of Sample/ Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y Comments: [ Arrived on site at 1218. Bailing began at 1220. Samples collected at 1225. Water _y.,_as mostly clear. Left site at 1229. Signature of Field Technician -::3,,,v,,-c---M~ ~~ -.:..~~YFVFTS Location ID Field Sample ID Purge Date & Time Sample Date & Time Purging Equipment Pump Type Purging Method Casing Volume (gal) Calculated Casing Volumes Purge Duration () pH Buffer 7.0 pH Buffer 4.0 Specific Conductance (micromhos) Date!Time Gallons Purged 5/20/2020 13:02 jvolume_ of water purg~dO [i=inal Depth to Water (f~tl Name of Certified Anal~ical Laboratory AWSL Analytical Samples Information Type of Sample/Analysis Chloride Nitrate/nitrite as N Comments: Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater PIEZ-03A Sampling Program Nitrate Quarterly PIEZ-03A 05202020 Sampling Event 2020 Q2 Nitrate 5/20/2020 13:00 5/20/2020 13:05 !sampler TH/DL Bailer Weather Conditions Sunny and windy Grundfos External Ambient Temperature (C) 20 2 Casings Previous Well Sampled PIEZ-01 0.94 7.0 Well Depth (ft) 79.00 4.0 Well Casing Diameter (in) 1 1000 Depth to Water Before Purging (ft) 55.85 Conductivity Dissolved Oxygen (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) (%) Before/After 1135 6.78 15.94 376 5.7 90.0 Pumpin_g Rate Calculations Flow Rate (Q = S/60) O Time to evacuate 2 Casing Volumes () 56.65 Number of casing Volumes Volume, if well evacuated to dryness () 0 Sample Container Preservative Collected? Matrix Number Type Sample Filtered? Type Added? y WATER 1 500-mLPoly u None N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y [ Arrived on sit~at 1259. Sameles bailed and collected at 1305. Water was mostly clear. Left site at 1310. Signature of Field Technician ~=~--c---h{~ Location ID Field Sample ID Purge Date & Time Sample Date & Time Purging Equipment Pump Type Purging Method Casing Volume (gal) Calculated Casing Volumes Purge Duration (min) pH Buffer 7 .0 pH Buffer 4.0 Specific Conductance (micromhos) Date/Time Gallons Purged (gal) 5/20/2020 9:47 5/20/2020 9:48 5/20/2020 9:49 5/20/2020 9:50 [volume of water purged (gals) [Final Depth to Wate_i-_(feet) Name of Certified Analytical Laboratory AWSL Analytical Samples Information Type of Sample/ Analysis Chloride Nitrate/nitrite as N Comments: 33.00 44.00 55.00 66.00 Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater TWN-01 Sampling Program Nitrate Quarterly TWN-01 05202020 Sampling Event 2020 Q2 Nitrate 5/20/2020 9:44 5/20/2020 9:50 !sampler TH/DL Pump Weather Conditions Sunny and windy Grundfos External Ambient Temperature (C) 13 2 Casings Previous Well Sampled TWN-04 24.97 4.54 7.0 Well Depth (ft) 106.13 4.0 Well Casing Diameter (in) 4 1000 Depth to Water Before Purging (ft) 67.88 Conductivity Dissolved (umhos/cm) pH (pH Units) Temp (deg C) Redox(mV) Turbidity (NTU) Oxygen(%) Before/After 894.7 6.48 15.30 369 9.0 60.0 897.0 6.50 15.27 367 9.1 63.0 894.0 6.50 15.28 366 9.2 62.0 897.0 6.51 15.25 365 9.2 61.0 Pumping Rate Calculations 66.00 Flow Rate (Q = S/60) (gal/min) 11.00 Time to evacuate 2 Casing Volumes (min) 6.00 102.88 Number of casing Volumes 2.00 Volume, if well evacuated to dryness () 0 Sample Container Preservative Collected? Matrix Number Type Sample Filtered? Type Added? y WATER 1 500-ml Poly u None N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y [ Arrived on site at 0939. Purge began_~0944. Purged well for a total of 6 minutes. Purge ended and samples collected at 0950. Water water mostly clear. Left site at 0953. Signature of Field Technician Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TWN-02 Sampling Program Nitrate Quarterly Field Sample ID TWN-02 05202020 Sampling_ Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 10:28 Sample Date & Time 5/20/2020 10:30 [sampler TH/DL Purging Equipment Pump Weather Conditions Sunny and windy Pump Type Continuous External Ambient Temperature (C) 14 Purging Method 2 Casings Previous Well Sampled TWN-07 Casing Volume (gal) 23.51 Calculated Casing Volumes Purge Duration () pH Buffer 7 .0 7.0 Well Depth (ft) 95.90 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 59.89 Dissolved Date/Time Gallons Purged Conductivity (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/ After 5/20/2020 10:29 2112 6.15 15.22 416 0 91.0 Pumping Rate Calculations jvolume of wat~_purged () Flow Rate (Q = S/60) (gal/min) 16.00 Time to evacuate 2 Casing Volumes O !Final De1>th to Water (feet) 68.95 Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratory AWSL Anal~ical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Comments: I Arrived on site_ at 1026. Sarrie_les collected at 1030. Signature of Field Technician Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan S -·~ ---l /~'-_._.I-:,--~,,..~s ~ ·-• ; ___ c., White Mesa Mill Field Data Worksheet For Groundwater Location ID TWN-03 Sampling_ Program Nitrate Quarterly Field Sample ID TWN-03 05212020 Sampling Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 10:51 Sample Date & Time 5/21/2020 10:35 [sampler TH/DL Purging Equipment Pump Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 15 Purging Method 2 Casings Previous Well Sampled TWN-02 Casing Volume (gal) 34.83 Calculated Casing Volumes Purge Duration (min) 6.33 pH Buffer 7.0 7.0 Well Depth (ft) 96.00 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 42.65 Conductivity Dissolved Date/Time Gallons Purged (gal) (um hos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/20/2020 10:55 44.00 2291 6.71 15.00 303 33.00 44.0 5/21/2020 10:34 2274 6.50 15.24 Before 5/21/2020 10:38 2280 6.53 15.20 After Pumping Rate Calculations - [Volume of water purged (gals) 44.00 Flow Rate (Q = S/60) (gal/min) 11.00 Time to evacuate 2 Casing Volumes (min) 4.00 [Fi.ii_al DeJ:)th ~ Water (feet) 94.05 Number of casing Volumes 1.26 Volume, if well evacuated to dryness (gals) 44.00 Name of Certified Analytical Laboratory AWSL Anal~ical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Comments: Arrived on site at 1047. Purge began at 1051. Purged well for a total of 4 minutes. Purged well dry. Purge ended at 1055. Water was murky. Left site at 1100. Arrived on site at 1031. Depth to water was 42.43. Same_les bailed and collected at 1035. Left site at 1038. Signature of Field Technician Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan e~ .. -._,·· ,· 7::-,' .r ~ "'"--":' /i • .· 1, ~~-ZS . --~·~ White Mesa Mill Field Data Worksheet For Groundwater Location ID TWN-04 Sampling f>rog_ram Nitrate Quarterly Field Sample ID TWN-04 05202020 Sampling_ Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 9:04 Sample Date & Time 5/20/2020 9:14 [sampler TH/DL Purging Equipment Pump Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 13 Purging Method 2 Casings Previous Well Sampled TWN-18 Casing Volume (gal) 42.80 Calculated Casing Volumes Purge Duration (min) 7.78 pH Buffer 7.0 7.0 Well Depth (ft) 126.40 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 60.85 Conductivity Dissolved Date!Time Gallons Purged (gal) (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/ After 5/20/2020 9:11 77.00 1039 6.55 14.83 381 1.3 67.0 5/20/2020 9:12 88.00 1037 6.57 14.83 382 1.6 66.2 5/20/2020 9:13 99.00 1036 6.57 14.85 383 1.6 65.9 5/20/2020 9:14 110.00 1034 6.58 14.83 384 1.7 65.8 Pumping Rate Calculations @~ul'll_e of water pu_rged (gals) 110.00 Flow Rate (Q = S/60) (gal/min) 11.00 Time to evacuate 2 Casing Volumes (min) 10.00 [ Final Depth to Water (feet) 62.20 Number of casing Volumes 2.00 Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratory AWSL Analyt_ical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Comments: !_Arrived on site at 0900. Purg_e began at 0904. Purged well for a total of 10 minutes. l:'.LJ!.Qe ended and samples collected at 0914. Water was clear. Left site at 0918. Signature of Field Technician ~-~..,~~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TWN-07 Sampling Program Nitrate Quarterly Field Sample ID T\NN-07 05212020 Sameling Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 10:13 Sample Date & Time 5/21/2020 10:15 jsampler TH/DL Purging Equipment Pump Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 14 Purging Method 2 Casings Previous Well Sampled TWN-01 Casing Volume (gal) 16.97 Calculated Casing Volumes Purge Duration (min) 3.08 pH Buffer 7.0 7.0 Well Depth (ft) 107.20 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 81.21 Conductivity Dissolved Date/Time Gallons Purged (gal) (um hos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/ After 5/20/2020 10:14 16.50 1830 6.42 14.99 401 2.0 74.0 5/21/2020 10:14 1784 5.90 16.00 Before 5/21/2020 10:16 1790 5.94 15.97 After @olume of water_purged (gals) Pumeing_ Rate Calculations 16.50 Flow Rate (Q = S/60) {gal/min) 11.00 Time to evacuate 2 Casing Volumes {min) 1.50 §nl!_I Depth to Wa!_er {feet} 106.02 Number of casing Volumes 0.97 Volume, if well evacuated to dryness {gals) 16.50 Name of Certified Analytical Laboratory A\NSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y \NATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Comments: Arrived on site at 1010. Purge began at 1013. Purged well for a total of 1 minute and 30 seconds. Purged well dry. Purge ended at 1014. \Nater was clear. Left site at 1017. Arrived on site at 1011 . Depth to water was 91 .52. Samples bailed and collected at 1015. Left site at 1017. Signature of Field Technician ~~~ Location ID Field Sample ID Purge Date & Time Sample Date & Time Purging Equipment Pump Type Purging Method Casing Volume (gal) Calculated Casing Volumes Purge Duration (min) pH Buffer 7.0 pH Buffer 4.0 Specific Conductance (micromhos) Date/Time Gallons Purged (gal) 5/20/2020 8:33 5/20/2020 8:34 5/20/2020 8:35 5/20/2020 8:36 !Volume of water purged (gals) l Final Depth to Water (feet) 99.00 110.00 121.00 132.00 Name of Certified Analytical Laboratory AWSL Analytical Samples Information Type of Sample/Analysis Chloride Nitrate/nitrite as N Comments: Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater TWN-18 Sampling Program Nitrate Quarterly TWN-18 05202020 Sampli11_g_ Event 2020 Q2 Nitrate 5/20/2020 8:24 5/20/2020 8:36 !sampler TH/Dl Pump Weather Conditions Sunny and windy. Grundfos External Ambient Temperature {C) 11 2 Casings Previous Well Sampled TWN-18R 55.49 10.08 7.0 Well Depth (ft) 147.00 4.0 Well Casing Diameter (in) 4 1000 Depth to Water Before Purging (ft) 62.02 Conductivity Dissolved (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 2667 6.17 14.55 350 1.0 1.2 2662 6.18 14.56 349 1.1 1.1 2659 6.19 14.55 347 1.2 1.1 2660 6.19 14.57 346 1.2 1.1 Pumping Rate Calculations 132.00 Flow Rate (Q = S/60) (gal/min) 11.00 Time to evacuate 2 Casing Volumes (min) 12.00 63.60 Number of casing Volumes 2.00 Volume, if well evacuated to dryness () 0 Sample Container Preservative Collected? Matrix Number Type Sample Filtered? Type Added? y WATER 1 500-ml Poly u None N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y I Arrived on site at 0821 . Purge began at 0824. Purged well for a total of 12 minutes. Purge ended and samples collected at 0836. Water was clear. Left site at 0839. Signature of Field Technician -.::3~-h'~ ..-.;s · ··~· ~··· /r l~~YFUEZS ·. .. J Location ID Field Sample ID Purge Date & Time Sample Date & Time Purging Equipment Pump Type Purging Method Casing Volume O Calculated Casing Volumes Purge Duration () pH Buffer 7.0 pH Buffer 4.0 Specific Conductance O Date/Time Gallons Purged (gal) 5/20/2020 8:13 132.00 !Volume of water purged() lfi'!~Depth to W~ter (feet) Name of Certified Analytical LaboratofY. AWSL Anal~cal Samples Information Type of Sample/Analysis Chloride Nitrate/nitrite as N Comments: Signature of Field Technician ~<AAJV.-C...--~~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater TWN-18R Sameling Program TWN-18R 05202020 Sampling Event 2020 Q2 Nitrate 5/20/2020 8:14 [sampler TH/DL Weather Conditions External Ambient Temperature () Previous Well Sampled Well Depth {ft) Well Casing Diameter() Depth to Water Before Purging (ft) Conductivity Dissolved (umhos/cm) pH (pH Units) Temp {deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 15.2 6.65 17.32 392 3.0 95.0 Pumping Rate Calculations Flow Rate (Q = S/60LQ Time to evacuate 2 Casing Volumes () Number of casing Volumes Volume, if well evacuated to dl}'.ness () Sample Container Preservative Collected? Matrix Number Type Sample Filtered? Type Added? y WATER 1 500-ml Poly u None N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TW4-22 Sampling Program Chloroform Monitoring Field Sample ID TW4-22 05272020 Sampling Event 2020 Q2 Chloroform Purge Date & Time 5/27/2020 9:34 Sample Date & Time 5/27/2020 9:35 [sampler TH/DL Purging Equipment Pump Weather Conditions Partly cloudy Pump Type Grundfos External Ambient Temperature (C) 22 Purging Method 2 Casings Previous Well Sampled TW4-24 Casing Volume (gal) 27.29 Calculated Casing Volumes Purge Duration () pH Buffer 7 .0 7.0 Well Depth (ft) 114.70 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 72.90 Conductivity Dissolved Date/Time Gallons Purged (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/27/2020 9:34 5326 7.24 16.48 348 0 90.3 Pumping Rate Calculations [_\,'_olume _of water J)_urg~d !)_ Flow Rate (Q = S/60) (gal/min) 18.00 Time to evacuate 2 Ca.sing Volumes () jFinal Depth to '4Yater (feet) 105.64 Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratory AWSL Analytical Sam_eles Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? voes-Chloroform y WATER 3 40mlVOA u HCI {pH<2), 4 Deg C y Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2504 (pH<2), 4 Deg C y Comments: I Arrived on site at 0931 . Samp_les collected at 0935. Water was clear. Left site at 0937. Signature of Field Technician ~, ... ~r~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TW4-24 Sampling Program Chloroform Monitoring_ Field Sample ID TW4-24 05272020 Sampling Event 2020 Q2 Chloroform Purge Date & Time 5/27/2020 9:24 Sample Date & Time 5/27/2020 9:25 !sampler TH/OL Purging Equipment Pump Weather Conditions Partly cloudy Pump Type Grundfos External Ambient Temperature (C) 20 Purging Method 2 Casings Previous Well Sampled TW4-25 Casing Volume (gal) 28.66 Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) 114.80 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 70.90 Conductivity Dissolved DatefTime Gallons Purged (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen (%) Before/After 5/27/2020 9:24 7951 7.08 16.00 347 25.0 19.4 !volume of water purg!Mi_() Pumping_ Rate Calculations Flow Rate (Q = S/60) (gal/min) 17.00 Time to evacuate 2 Casing Volumes O !Final Depth to Water (feet) 78.23 Number of casing Volumes Volume, if well evacuated to dryness () 0 Na.me of Certified Analytical Laboratory AWSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? voes-Chloroform y WATER 3 40ml VOA u HCI (pH<2), 4 Deg C y Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2S04 (pH<2), 4 Deg C y Comments: [ Arrived on site at 0920. Samples collected at 0925. Water was clear but had little bubbles surfacing. Left site at 0927. Signature of Field Technician ~~~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TW4-25 Sampling Program Chloroform Monitoring Field Sample ID TW4-25 05272020 Sampling Event 2020 Q2 Chloroform Purge Date & Time 5/27/2020 9:13 Sample Date & Time 5/27/2020 9:15 [sampler TH/DL Purging Equipment Pump Weather Conditions Partly cloudy Pump Type Grundfos External Ambient Temperature (C) 20 Purging Method 2 Casings Previous Well Sampled TW4-21 Casing Volume (gal) 43.62 Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) 136.70 pH Buffer 4.0 4.0 Well Casing Diameter (in) 4 Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) 69.89 Conductivity Dissolved DatefTime Gallons Purged (umhos/cm_) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/27/2020 9:14 2514 7.12 16.05 311 0 42.0 [volume of _!tater purgedJl Pumping Rate Calculations Flow Rate (Q = S/60) (gal/min) 12.6 Time to evacuate 2 Casing Volumes () !Final Depth to Water (feet) 89.23 Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratol)'_ AWSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? voes-Chloroform y WATER 3 40ml VOA u HCI (pH<2), 4 Deg C y Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2504 (pH<2), 4 Deg C y Comments: [ Arrived on site at 0910. Samples collected at 0915. Water was clear. Left site at 0917. Signature of Field Technician ~a~~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TWN-60 Sampling Program Nitrate Quarterly_ Field Sample ID TWN-60 05202020 Sampling Event 2020 Q2 Nitrate Purge Date & Time 5/20/2020 13:26 Sample Date & Time 5/20/2020 13:30 [sampler TH/DL Purging Equipment Pump Weather Conditions Sunny and windy Pump Type Grundfos External Ambient Temperature (C) 20 Purging Method 2 Casings Previous Well Sampled PIEZ-03A Casing Volume () Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) pH Buffer 4.0 4.0 Well Casing Dia'!leter () Specific Conductance (micromhos) 1000 Depth to Water Before Purgingjft_) Conductivity Dissolved Date/Time Gallons Purged (umhos/cm) pH (pH Units Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/20/2020 13:29 2.2 7.25 19.75 333 0 19.3 Pumping Rate Calculations jVolume of water purged () Flow Rate (Q = S/60) () Time to evacuate 2 Casing Volumes () [Final Depth ~_Water (feet) Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratory AWSL Analytical Samples Information Sample Container Preservative Type of Sample/ Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y Comments: [ Arrived in lab at 1325. DI sample was collected at 1330. Left site at 1333. Signature of Field Technician -2),~~d~ Groundwater Discharge Permit Groundwater Monitoring Quality Assurance Plan White Mesa Mill Field Data Worksheet For Groundwater Location ID TW4-60 Sam_eling Program Chloroform Monitoring Field Sample ID TW4-60 05272020 Sampling Event 2020 Q2 Chloroform Purge Date & Time 5/27/2020 13:09 Sample Date & Time 5/27/202013:10 [sampler TH/DL Purging Equipment Pump Weather Conditions Partly cloudy Pump Type Grundfos External Ambient Temperature (C) 28 Purging Method 2 Casings Previous Well Sampled TW4-40 Casing Volume () Calculated Casing Volumes Purge Duration () pH Buffer 7.0 7.0 Well Depth (ft) pH Buffer 4.0 4.0 Well Casing Diameter () Specific Conductance (micromhos) 1000 Depth to Water Before Purging (ft) Conductivity Dissolved Date/Time Gallons Purged (umhos/cm) pH (pH Units) Temp (deg C) Redox (mV) Turbidity (NTU) Oxygen(%) Before/After 5/27/2020 13:09 1.0 7.71 22.10 333 0 95.0 Pumping Rate Calculations [volume of water purged () Flow Rate (Q = S/60) () Time to evacuate 2 Casing Volumes () !Final_!)epth ~_Water (feet) Number of casing Volumes Volume, if well evacuated to dryness () 0 Name of Certified Analytical Laboratory AWSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? voes-Chloroform y WATER 3 40mlVOA u HCI (pH<2), 4 Deg C y Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HDPE u H2S04 (pH<2), 4 Deg C y Comments: j _Arrived in lab at 1305. Samples collected at 1310. Left site at 1312. Signature of Field Technician ~-····'-'-'- Groundwater Discharge Permit e~-.:· . ..~-. ,l-' -----; -· ... -·l' '....I, . , -~/· ·~y~s ' ':<"' • White Mesa Mill Field Data Worksheet For Groundwater Groundwater Monitoring Quality Assurance Plan Location ID TWN-65 Sampling Pl'_og_ram Field Sample ID TWN-65 05202020 Sampling Event 2020 Q2 Nitrate Purge Date & Time Sample Date & Time 5/20/2020 9:14 !sampler TH/DL Purging Equipment Weather Conditions Pump Type External Ambient Temperature _O_ Purging Method Previous Well Sampled Casing Volume () Calculated Casing Volumes Purge Duration O pH Buffer 7.0 Well Depth (ft) pH Buffer 4.0 Well Casing_ Diameter () Specific Conductance () Depth to Water Before Purg_ing_(!!) Date!Time Gallons Purged Conductivity eH Temp Redox Turbidity Dissolved Oxygen I Before/After I jvolume of water purged O Pumping_ Rate Calculations Flow Rate (Q = S/60) () jFinal Depth to Water (feet) Time to evacuate 2 Casing Volume~) Number of casin_g_ Volumes Volume, if well evacuated to dryness () Name of Certified Analytical Laboratory AWSL Analytical Samples Information Sample Container Preservative Type of Sample/Analysis Collected? Matrix Number Type Sample Filtered? Type Added? Chloride y WATER 1 500-ml Poly u None N Nitrate/nitrite as N y WATER 1 250-ml HOPE u H2504 (pH<2), 4 Deg C y Comments: I Duplicate of TWN-04 Signature of Field Technician -=:)'"'"'-"'°~~ TabC Kriged Current Quarter Groundwater Contour Map, Capture Zone Map, Capture Zone Details Map, and Weekly, Monthly and Quarterly Depth to Water Data Date Time 5/5/2020 1224 5/5/2020 1453 5/5/2020 I I 18 5/5/2020 958 5/5/2020 1040 5/5/2020 1001 5/5/2020 1030 5/5/2020 1026 5/5/2020 I 100 5/5/2020 1219 5/5/2020 1207 5/5/2020 1310 5/5/2020 1305 5/5/2020 1459 5/5/2020 1405 5/5/2020 1405 5/5/2020 1035 5/5/2020 848 5/5/2020 1409 5/5/2020 1352 5/5/2020 I 130 5/5/2020 1524 5/5/2020 1519 5/5/2020 1515 5/5/2020 !Oil 5/5/2020 1017 5/5/2020 1503 5/5/2020 1506 5/5/2020 1021 5/5/2020 1319 5/5/2020 1315 5/5/2020 1055 MW-26=TW4-15 Comments: MW-32 = TW4-17 Name: Deen Lymnn. Tanner Holliday Dn1e: 5/4/2020-5/5/2020 Depth to Well Water (fl.) Date Time MW-OJ 64.51 5/4/2020 921 MW-02 109.77 5/4/2020 927 MW-03A 83.98 5/4/2020 916 MW-05 108.21 5/4/2020 1106 MW-II 85.25 5/4/2020 944 MW-12 107.15 5/4/2020 1115 MW-14 102.28 5/4/2020 1055 MW-15 105.31 5/4/2020 1058 MW-17 71.59 5/4/2020 I 102 MW-18 73.26 5/4/2020 I I 13 MW-19 64.63 5/4/2020 1119 MW-20 89.71 5/4/2020 910 MW-22 66.49 5/4/2020 1038 MW-23 I 17.15 5/4/2020 1035 MW-24A 112.03 5/4/2020 1028 MW-24 I 10.94 5/4/2020 II23 MW-25 79.63 5/4/2020 1130 MW-26 85.63 5/4/2020 JOJO MW-27 57.17 5/4/2020 838 MW-28 74.70 5/4/2020 804 MW-29 107.75 5/4/2020 828 MW-30 75.23 5/4/2020 1052 MW-31 68.48 5/4/2020 821 MW-32 80.25 5/4/2020 809 MW-33 DRY 5/4/2020 1048 MW-34 107.61 5/4/2020 900 MW-35 I 12.38 5/4/2020 1041 MW-36 l 10.60 5/4/2020 1025 MW-37 113.55 5/4/2020 1015 MW-38 70.03 5/4/2020 904 MW-39 64.88 5/4/2020 1044 MW-40 80.15 5/4/2020 857 5/4/2020 1022 5/4/2020 1018 5/4/2020 1032 5/4/2020 834 5/4/2020 IIJO 5/4/2020 843 5/4/2020 952 5/4/2020 937 5/4/2020 853 Depth to Well Water (ft.) MW-04 88.70 TW4-0I 106.14 TW4-02 I 10.21 TW4-03 63.31 TW4-04 80.33 TW4-05 70.55 TW4-06 78.02 TW4-07 82.78 TW4-08 86.15 TW4-09 68.55 TW4-IO 67.97 TW4-ll 90.60 TW4-l2 54.78 TW4-13 56.12 TW4-14 77.65 TW4-16 72.40 TW4-l8 71.60 TW4-19 68.18 TW4-20 69.90 TW4-2l 72.12 TW4-22 70.23 TW4-23 74.61 TW4-24 69.51 TW4-25 72.45 TW4-26 72.60 TW4-27 78.97 TW4-28 47.99 TW4-29 77.53 TW4-30 75.08 TW4-31 76.57 TW4-32 55.55 TW4-33 77.05 TW4-34 75.72 TW4-35 75.07 TW4-36 57.65 TW4-37 76.17 TW4-38 58.79 TW4-39 85.05 TW4-40 71.77 TW4-41 88.02 TW4-42 68.60 Date Time 5/5/2020 121 I 5/5/2020 1203 5/5/2020 1429 5/5/2020 1044 5/5/2020 1049 5/5/2020 1445 5/5/2020 815 5/5/2020 1435 5/5/2020 1418 5/5/2020 1215 5/5/2020 1228 5/5/2020 1240 5/5/2020 1236 5/5/2020 1414 5/5/2020 1300 5/5/2020 1338 5/5/2020 1334 5/5/2020 1005 5/5/2020 1349 5/5/2020 1345 5/5/2020 1329 5/5/2020 I I 13 5/5/2020 1109 5/5/2020 I 104 5/5/2020 1355 5/5/2020 1324 5/5/2020 1359 5/5/2020 1403 5/5/2020 1420 5/5/2020 1425 5/5/2020 1408 5/5/2020 1430 5/5/2020 1412 Well PIEZ-01 PIEZ-02 PIEZ-03A PIEZ-04 PIEZ-05 TWN-01 TWN-02 TWN-03 TWN-04 TWN-06 TWN-07 TWN-14 TWN-16 TWN-18 TWN-19 DR-05 DR-06 DR-07 DR-08 DR-09 DR-IO DR-II DR-12 DR-13 DR-14 DR-15 DR-17 DR-19 DR-20 DR-21 DR-22 DR-23 DR-24 Depth to Water (ft.) 66.49 43.95 55.93 65.71 64.44 67.85 59,80 42.72 60.88 79,67 82.12 59.36 47.40 62.1 l 53.79 82.77 94.23 91.34 51.52 86.43 78.25 98-41 91.56 69.20 75.75 92.36 64.78 63.20 55.51 100.16 DRY 70.38 44.00 .... "". Monthly Depth Check Form . ·"1 .. Date Yb (r2:0UJ Name .D~f\ L~tvt,v, , ..,;. .. "~,-J./o JJ,'J"(! Time Well Depth* Time Well Depth* 'r ; LQLQ MW-4 S9.~S l~ TWN-1 b7.5.5 taa1 TW4-1 lQ2., ~2. Id.I~ TWN-2 18. I 10 IQ t S: TW4-2 U 1.,1 1.1c~ TWN-3 ~1~1 10~3 TW4-3 (;,~ .7' 11.11. TWN-4 ~(').1{5 lQO.Q TW4-4 80. Li. ,~ob TWN-7 fl 1-3 I lQJ~ TW4-5 7{). Ll l.61~ TWN-18 c..t.1,5 0955 TW4-6 771 "I~ 12.0 :1> MW-27 s,.b.s , ,aL2. TW4-7 sa.:i~ 1!51 MW~30 7'i. 7'j ta.a1 TW4-8 i:<1 sf ll5~ MW-31 ~S.73 ia 31 TW4-9 ~8!QB lQ3B TW4-10 ~Z, ':1.. 6" lQIS TW4-11 90.1~ Q9;ll TW4-12 5~ . .;;t3 09l8 TW4-13 2~, '5~ og.15 TW4-28 ~1,2..fa 0'1.L l TW4-14 7 7.1./ ;;i_ Q8~j TW4-29 71.IJ~ LQ':J.'1. TW4-15 1'1, LS: Qi3Q TW4-30 '14.' l LQ'.:J.:J.. TW4-16 7Z,sa OSJ.1 TW4-31 7,.1~ ll~l'> TW4-17 g();,5 ag.aa TW4-32 . s.~.B.O. I ::i.;i.c..,. TW4-1'8 ]1.J.5 ns.:z Q TW4-33 7'1.,'23 12.'i5 TW4-19 7Q .J, 083S TW4-34 Zi,.2 i · \ LQ51 TW4-20 :zg.11 "83~ TW4-35 "2.'d.,la ~ lil~ TW4-21 73..0 1 09.l r; TW4-36 ,; z 'J.. t./ 1 I 'i7 TW4-22 l/:1 ,65 u25.g_ TW4-37 7':l..l! O!_~lJ TW4-23 7':f..t), lQ,8 TW4-38 2.S., :J. ~ 11 i.t.5 TW4-24 bl I gt:. JQ2.0 TW4-39 12,3~ l~J TW4-25 10:z .. 73. 0939 TW4-40 12aQ3 09.L/~ TW4-26 :Z.l,'1.7 lQQ _3. TW4-41 81.18 0823 TW4-27 · 78, 5$" as,, TW4-42 ,1,98 Comments: (Please note the well number for any comments) * Depth is measured to the nearest 0.01 feet Weekly Inspection Form Name...v~00"'7 k« ~~' · · : System Operat~al (If no note Date Ti me W II e D th* C ts bl / I ·1 l ep, ommen anx ero ems correct ve aci ons nq,:.::,, MW-4 q'.l. ~~ Flow '3. SJ 'ieg No Meter .2.uq~q ~ 1 tJ ~ -No ,•' .. 11q~~ MW-26 9,1././2 Flow 1n ~ 'as No Meter I./~ 4 ~ ..2 ~ 6, \a No IO'l c, TW4-19 /-Cf 7~ Flow Jfl n Va No Meter .:, , n~1-1 7 J:; ~ .._ No nq:i.-,. TW4-20 .r. 1§:1 /') ~ Flow 4.fJ 'ies No Meter 1 J ~n ~ .,__ c;-~ -· No /{)07 TW4-4 « (" q (' Flow / '( I./ ... -No -Meter c.qLU. 7~ ~ -No '10/1/') TWN-2 /..« ".I r, Flow 17,/-~ No Meter ).'.)_gr.~ cz~.r--No ,?q/~ TW4-22 7:J ./J~ Flow I&. l.,J Yea No Meter t:.q ~"" ~ .7 Vm No lnol'J~ TW4-24 ~11 71 Flow I 1./. '1. 'ta No Meter/'~ .1 ~ 1 Jir c; :2 ._ No J?4jlt;~ TW4-25 Q !l II Flow 12 /,. 'a No Meter ""~" 1_c; ~ ~ --No /}~~7 TW4-1 ,n~ tJ::\ Flow Jt../ 0 ~ No Meter :3 :,~90 3 , Ya, No oq,u. TW4-2 II :1 "1"'1 Flow /7. ~ v.e No Meter ~7g~ .:z 7 S:1 'ID No nq~4 TW4-11 ttn ~, Flow Jt;. ~ Yea No Meter t;; 1 ~ 'i q. ~ V. No I]«"{~ TW4-21 71. -,.r Flow J 7 /-._ No Meter ~ 1 if.,-:=;,.-,_, :::1.3 Vas No nq1~ TW4-37 ~ I • .:t."T Flow ,g D "88 No Meter , ., 1 q 'l r • .., 'A '1111!9 No 114..lA TW4-39 .., !.1 ,. .'.) Flow HI /'J V:e, No Meter 6. 1 ~ o o '5. <' ~ No JOJ a./ TW4-40 7/ /_U Flow /'if,/1 "-No Meter "'1 ,._ , /,.-,. . .., "' V. 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No Meter -:t ~ 1 ~ ~ LI (') ..... No oq~~ TW4-11 Qt:1.fl<" Flow JI •. ,g ._ No Meter .-:. ~ .:i , 7 4 't:es No 07&:7 TW4-21 7~ :l I Flow Jt....O ¥ID No Meter ~ _j 10 75 &:. :'1 "J -.e No n~"' n TW4-37 ila ,-, Flow I~ n "8· No Meter , -, ,. 1 , , q .:i. 'i!a No 11>~«.n TW4-39 ~I{ 1../~ Flow I~ n V. No Meter 1,,.. 1.-1 , c;-,r ~ "i ... No Jn1q TW4-40 .,, 7, Flow "' n ~ No Meter "'"~,. q ,;-, , ~ 'la» No J nn 1, TW4-41 ~1 l'::l Flow ,;-: Si' "-No Meter ~ , ~ .-;. ,; .:> • ~ S--'Mt No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): • Depth is measured to the nearest 0.01 feet. Weekly Inspection Form Name~,, :z;:;;,,c: 4/a!l~~c ' ··· System Operatlo :, (If no note Date Tl me W II e D th* C ts bl / ct -eo· ommen an)! ero ems corrective a Ions} ,,. oq-:11 MW-4 ~ « .., n Flow 'I. n ~ No Meter ~ e:-~ qr,n -,.« 1 \a No .. .. O~'I~ MW-26 'i?~. r.. ':\ Flow ,, :l .... No Meter 11., 1.., q l.. ."l, "-No I nl fJ TW4-19 1.:q ,~ Flow -Yes .r!t> Meter .2 , !) CJ , 7 r-, Yes ~ 117~:111' TW4-20 t;q </!) Flow :2. ~ v.. No Meter "lrq3 o~ "-1> ._ No ()'141/ TW4-4 ~o '7s ~ Flow JI'. 0 ., 'cs No Meter ~qlf~ ~1., 'a No n"'~ TWN-2 <e:t.~O Flow IC. <.I -No Meter 1 ~ 4 r,.. ~ ~ , -i. .... No . log.:i ca TW4-22 7a ".l '2. Flow )t,l' 0 Vet ·No Meter 7on~·'ln R '"91 ·No 0'82 l TW4-24 raq r;-1 Flow Jq.~ 'M No Meter 1 "3 ; q -r 11 ~ n A "89 No IH\nQ TW4-25 -,~.~,;-Flow I '2 &./ ¥es No Meter H &"' .., r;-t:". "' ~ w. No oq'J..., TW4-1 1n~ IL/ Flow 1""-n -No Meter~ ".l "'f9. '2 tfl 7 ~ No oq If,, TW4-2 Jl/1 ~, Flow /ti>." *8 No Meter ~ ~ ~ r-"'> -, n Y£t No l)q It? TW4-11 On ~.IJ Flow I~.« ~ No Meter /.<A" :J J S--~ No IJ'Afll./ TW4-21 -, .:l I !1 Flow ,,."I Vas No Meter ~ '1 1 is1-, .2.., n-, ¥a No /'1<13" TW4-37 7/. I 7 Flow 1« I) ~No Meter , 7 1 'T t:J 11 " WES' No /'J ~,., ':I TW4-39 9.. ,;-. t1 Ii"-Flow J'l,LL 0 *-No Meter ~""::i ,:~ . .., \ v.·· No {)q,;'.:J. TW4-40 -,, ..,.., Flow Jq ,I') 'i(e$ No Meter ~"" t:,"7 !I ~ "l c--Ye No l)q37 TW4-41 ~11,.0!l Flow LI 41 ¥11119 No Meter ~ ., q_ "7 ..1 7 ."4. ~ No ... Operational Problems {Please list well number): Corrective Action(s) Taken {Please 11st well number): ---------------- • Depth is measured to the nearest 0.01 feet. Date z: .. U-+a Weekly Inspection Form Name D«n C; 4':mtaa < ·~· .... Svstem Operational (lf,no:note Ti me W II e 8D C ommen ts bl t ., an~ 2ro ems corrective actlonsl 1nr,Q MW-4 'il:fll ''1 Flow ""· n Y!m No .. Meter ...., c--=-~ "7"o..,, .J ~ No /,CJ,t;'I .MW-26 741 ~I'-Flow 'l. ~ ~ No Meter 11 .., 1 ,:; n '4 '.l ~ No JIJL{t( TW4-19 7( 4"2. Flow I/_ ll .._ No Meter ~ 1 -:a.. c:re1 1, " 'Gm> No lnQWI> TW4-20 ~q qb Flow 2.4 ~ No Meter "2,._.,4q"·~'"' ~ No 1n~I-TW4-4 ~a;' 41 ~ Flow '"-n .., ._, No Meter ., "'" , -, ":a. .., -No ll!QJ « TWN-2 t;'q. Jfl Flow J ,_ <;r "ie& No Meter , !:> C'I ~ ~ qc:p ,_ \!Is No A ,0 '!:I CII TW4-22 7R 1~ Flow ,r1 n ,.V:e,. No Meter -,d1 ".J u/.. , '3 No /JDl-:l &J TW4-24 7/ 77 Flow. I I":..'-/ 'ta No Meter , 2 " ·141 n 1o1 n <" ~ No lncu,,;-TW4-25 C.Cf.~ ~ Flow J~ ~ 'te:a No Meter ,., 7 ,._ -:1 7 7 "' 7 ~-t NO ,n,r:: TW4-1 1n,_ .~n Flow I~ . ...., 'ts»· No ., Meter ~ 'l r; c;-, -, ~ 'ms> No Mnu TW4-2 IIL~7 Flow I£. '.), ¥:D No . Meter 4Q C:a Q 4~. :::i. -No nQ,:« TW4-11 q I. 0"3 Flow Jt:.. st 'a No Meter ,:.. Q c:-,_· ~ 1.1 ~ No ... _ -~ TW4-21 '7ft ,,, Flow , .., ct 'ta No Meter -" "I "" I'" ,Q -r I I n 'am No "'1~-::\ I:' TW4-37 "f !I .., 14 Flow ,,. I? Ya) No Meter , -, ,11 o "" '1. « ~ No I J')Q 1.4 e;' TW4-39 r.l&.f. l.(J Flow 1« n Yd No Meter 6,.,-, 9. OJ ,. 'l ~ No ,n~"'.1 TW4-40 •u .~« Flow I« ";,n .._ No Meter .,,,.r .. ,,, u u "'.,. Vm No Jtl~ I TW4-41 Q'T , ' Flow ·~ 'l '*" No Meter ~ a n Cl 1 &f. , Q ._ No Operational Problems (Please list well number}: Corrective Action(s) Taken (Please list well number): ----------------- • Depth is measured to the nearest 0.01 feet. Weekly Inspection Form Name:;z:J,za ,,.~-i~;crn00 . · " :· System Operational (If no note Date r~ 151 _ ;..a r· W II D th* ,me e eo C ~ b i ommen an~ ~ro lemslcorrectlve ac Ions} /Jq I.( .:l MW-4 ~0 O::J. Flow If~ 0 )a No· Meter .:i., LfJ../ 3 '\ 7 °''"' lt!iS No .. .. nq,.., MW-26 ~c;? 7 9,, Flow I I'} -2 'ta No Meter J.J7<~oq ~ ~ No J3 c; ('} TW4-19 7~ 1)9, Flow II .. n v.· No Meter :11 t;' 1 c;:r, ~ ~-i 'a No ()q I> t:j' TW4-20 ~« I'..~ Flow J./ 17 .._ No Meter '3 7 7 7, "' '1 , ... r1 '9 No JOD9. TW4-4 st 5'.:. ¥ ,;-Flow J .J. (,,. ... 'ta No Meter 7 /J / :2 q 9. c;-~ No f,)~ -a.() TWN-2 , Z::'1. i (1 Flow HLO ~ No Meter , s (") o c. , 7 n ~ No n~ t;' '-I TW4-22 71. ~st Flow I~ 0 -No Meter 7,, """ , ~ c. c;1 ~ No n~i-4 C: TW4-24 (;,' ~.!-I Flow I c;' . .:l ~ No Meter J J l.f 7 t. J" ~ 4 ¥a No In~~~ TW4-25 7.:l .Or; Flow JOU ... No Meter '-/ (j/ 2.-, fJH? q {) .,.. No ,? tCf,.., 9i TW4-1 ,n~ -:::i.n Flow J"'I 0 ~ No Meter ~ ~ f.. :::1 q o L.J ~No t,q'?, /,. TW4-2 I /J"1 ~ /,. Flow I., ~ -No Meter 1 ~ t./ ~ J.f sr. ~ ¥15 No nq.-...n TW4-11 qn41 Flow J ;, /j 'ta No Meter t;, 'it 1 1 n -; ~ No ()fl It;' TW4-21 7q., 1 Flow J {,. '1 "mo No Meter ..2 .:, ~ 4 Q. "A 4, 7> .., ~ No nq<"q TW4-37 ,"'1,,~~ Flow Jg I) ¥:5 No Meter , -, 1.-11-'T.Q t ... , W:!S No 1~q1 I TW~39 7'b . / ~ Flow t SL 0 )!a No Meter /-'-fq ~-, Lf, q ~ No IOI£/ TW4-40 ,, ~n Flow i~ I} ~ No Meter 4 /~n ~ n J q ,._ ~ No /)ql{"q TW4-41 ~7,q1 Flow t,,0 'ta No Meter i 'if !l I t,>fl. ; 7 ~ No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): * Depth is measured to the nearest 0.01 feet. .. Weekly Inspection Form Date , .. ,i,-aa Name72",, . ·: .. · System Operational (lf.no:note Time W II e Deoth* C t ommen s an~ ero b ·t lems/2_2rrectlve actions} /JO,;~ MW-4 c:ro on Flow ,., n ~ No .. Meter ~ t; e;-,. n '.) 7 n,. 'GIB No flQ:l2 MW-26 ~IJ Hl Flow ,.n ~ " No Meter 4 ., ., ~ 7 o a YD No /I L.j c;-TW4-19 ..,~ "'Ir... Flow J (,,, (ii -No Meter '.l , r. r_ ':l .., ,, '"J, ~ No lnq~~ TW4-20 ~a t4' Flow ~-'· ~ No Meter '\ " T q "l "'I ,_ -:1 ~ No ,n ,.,;-TW4-4 it ,. ,. -z. Flow J 4 '-/ .,. lga No Meter .., ,, '.J " " 1 , ~ No t?Qnn TWN-2 ~ca ~, Flow J "1 "-'ma No Meter i , n "\ ~ -:::i o .., 'm No nQI~ TW4-22 '"7 !.I . ':I. ".l Flow J'ill.n ~ No Meter -rn&~ f\Q. ,_ Y:es No TW4-24 Flow . ~ No q /}(J/JI--,n C"n JI'. 9J Meter , ~ <' ~ t:. 1-, -," ¥Es No In,,,·.~ "'1 TW4-25 ,:.q "I :7 Flow J ~-. ,,. 'tes No Meter ",10 , t .. '1 "" ~ ~ No 1,inn TW4-1 11'1 '-,I(_ Flow '~ ~ 'ms No Meter -::1 !:l-, •-, ., ..., 'mt No /)QJ.1"1 TW4-2 I I() t.a Flow ,,.,.n 'tBs No Meter ~«.i: n,, c:-~ No " nqu!J.. TW4-11 4n .,,:: Flow J r:. st ~ No Meter. £..a•~ a. .. ~ 'ts No n·AM"':l TW4-21 '7"1...,~ Flow //.. ~ "tea No Meter ~ ..2 l,I' , ~ .c" ., . ,:-,,,,,. ~ No J?OHI. TW4-37 .,,. ~n Flow 1« 0 ~ No Meter I.., "" "'I '!I "'I r_ . <l ~ No [J?,O'?Cl TW4-39 at: ~c;-Flow .~ " ~ No Meter 1.~.2.~ :::1, 11; ~ No 1n!1~ TW4-40 -, I Q Q Flow J9C.IJ V. No Meter .., t',..Q £. Q, • ., ,. Y, No inn-, TW4-41 o.q nt.1 Flow I'.. n ~ No Meter "'I cz ~ 1~ 1. ., ., /_ .._ No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): * Depth is measured to the nearest 0.01 feet. Weekly Inspection Form System Operati::af (If ncfnote Date r,-, ... a,q Ti me W II 8 D th'* C ts bl I I l.' 80' .ommen an:it: ero ems correct ve ctlons) t I} :J c;( MW-4 9t c;' J.f c;-Flow '-'. /) V..-No .-.. Meter .:1 r.:-r:::'qC:-:i 8 ~ ~ )fea No t,q~t:,, MW-26 -, I C:'if Flow In SI -No Meter "7'A 711 ~ -No I I "4 q TW4-19 ,~ &; ~ Flow 1, n 'a-No Meter :i , , "" '3 q ~ti \a> No lnq!:J..q TW4-20 qi,"', t;,O Flow 'l'"-~~ J-1 I) V. No Meter ~ q ,;--t:, 1 ·i 7 I v.,. No 1nL.1~ TW4-4 ~~ 17 Flow ·~ J:J..9. V.. No Meter 7 n ~ LI n a. . ~ ~No I') ti '1 I TWN-2 ~~:, I Flow It. tJ -No Meter , .,,_ n er-.c-g ,;-,. , --No 1/'JQ/(/. TW4-22 ti. I{. 1,;-Flow J'il_t1 ... No Meter "7 n 7r.. , t:'. 7 .. No I/JQ I ;J TW4-24 r:. 4 4 '">. Flow /.I"!. /) ~ No Meter , -,. t:;' t;,. 1 t:. 1 Ii''/ *8 No n -« i:-er TW4-25 ~st nr Flow II. '.l .._ No Meter 41q.t;'"9tiJ1~.Q ".l >ta No - )(}'l.LI TW4-1 I l'1 :, /,,,,./',. Flow J~ ~ ies) No r Meter ~::i_-,1-4~~ (.' res) No , n, ..:l TW4-2 , n1_ ~n Flow Ir,. :J ~ No Meter ·::uu. Sl t..: \ -, -No " JntJ:i. TW4-11 qJ 0~ Flow 1, ... ,..., 'mF No ,, Meter c;;&q q 4 « ._. No =. lnff .::i '1 TW4-21 7¥ "51q Flow I I. c.( >as--No Meter ~ ~ ,: n t: o 2 st h Via No l'Jq.:1. ~ TW4-37 ,:,~ ~/,. Flow Ul .. n .__ No Meter t 7 -t"" {,. If 7 ::i , ftl&> No ll)Q t:('/) TW4-39 ~~."(t;°' Flow I Cl IJ V.. No Meter.. , _ 'i' J.J /n 7 ~ / 'all> No JOit~ TW4-40 -,, ,cf< Flow "'· I) ~ No Meter '"''""'/A~ t~. if"~ "'8r' No J n'1iq TW4-41 Q'.t;' ,.,; Flow I:'. -.::2 --No Meter ~ ~ ,_, 1o -, ~ . ,_ n ~ No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): ---------------- * Depth is measured to the nearest 0.01 feet. Monthly Depth Check Form . , 1., Date f, _ 'i _ J..O Name;z2,a <r't47 ~/t,f,' i Time Well Depth* ;,, t ~ Time Well Depth* · i 3 3.a.. MW-4 i9.!!Q ,,,.,, a za a TWN-1 ~1. a..1 ..... ···.' TW4-1 .TWN-2 l3 .at lQA. I~ l~l,g 2'2,':J.~ l3 3 5'.: TW4-2 H2 !, a.I QJO;-" TWN-3 ~:::i...u. ,. 11S:.2. TW4-3 -C.3, 1! a1a9 TWN-4 1-fJ..1!'4 i3 .2.1 TW4-4 is:. a.!i (2 I.il.!i TWN-7 sr1.ga. ,r" ,~ 13 TW4-5 ZQ. '2Q Q:Z:.I !:1 TWN-18 ,a.. Q~ Q9!:l s:: TW4-6 ::Z7, 9 !:I a:x 19 MW-27 57.LQ ... ,. l3!:1 I TW4-7 is .a .-:ia a13S: MW-30 :ZS:,123 ,IC « ll!:l:Z TW4-8 S!a:,91 l~]Q MW-31 ,s.~u .. ~ l!:IIJg TW4-9 tit!, '1.Q . ,. l~ll TW4-10 {a-1.QZl Ul11 TW4-11 9'2,11 aga.3 TW4-12 !l'"I, Zl O'l.a.a TW4-13 5:'..t;"'.!f~ aga:z TW4-28 ~1.g~ agi3 TW4-14 21.~~ aS."ll TW4-29 ,:I.!::lS: i !:ta.a TW4-15 StJ.3S: « ata.s TW4-30 l~sS!:l / ':1 ., TW4-16 72,34 a1a't TW4-31 zt,,,_.~1 ' l ~ .a.t. TW4-17 ia.9.:z ag3a TW4-32 ~~~a " lS'.JS: TW4-18 :ZI o::Z I Q.8t&a TW4-33 Z1,Ql IS: .1.a TW4-19 :13, 5i.O. QB!l TW4-34 I<-l4 t.. l~~fJ. TW4-20 7.Q, Q(i_ t.lS.33 TW4-35 7.~.g":J_ n:ia TW4-21 72, (.f o,,, TW4-36 'i7, « . l 'i.!:l.S TW4-22 e.g. a:1 ·· ,~~!:#. TW4-37 1a. lS a!l.!:I.~ TW4-23 2~.,;:._,:-1!:ill~ TW4-38 (8,"~ H:iS:3 TW4-24 1.19.gs: l ~ 3:Z TW4-39 z.a. .. !a , ,:as: TW4-25 :ZC., l3 0!3S:: TW4-40 '2. l, 8.~ ~· "~38 TW4-26 7.d. I ,; f;;" 13i:l.S: TW4-41 SQ,ll os,o TW4-27 76, ft 1 08 f, TW4-42 t.8,0 Comments: (Please note the well number for any comments) * Depth is measured to the nearest 0.01 feet I Weekly Inspection Form Date ,-s-a..o Time ell eot ommen s an~ (!ro lams/corrective actronsl w D h* C System Operatlo~I (ti. nd·,note t b .• ,,,-1/Jq//j MW-4 "4r ?« Flow "'-n Vs No . ,... .~ Meter '.1 i:-1~ "-~ q n ~ u .. No 41 [/)'AI.//J MW-26 -.,c ac Flow '" ~ "-No Meter "'tZ o -:j "1:. o )fee No J/4t:; TW4-19 ..,C" ~ q Flow J "1 . l'J ¥ea, No Meter .2 ,'~q a:;-q.c;t /_ ~ No /'J~1.n TW4-20 ..,,_ "'" Flow ~ ., "' ._ No Meter ""'tJ .,, 1 q ,. "' , V. No loq°~,_ TW4-4 "er .., " Flow ,·~ r, ... "-No Meter 7;, ,./w 1 -:a ,., Yes No ln'7u.., TWN-2 cq i':I Flow '7 '.'.) 'lea No Meter , ~ri .,~ Q 4 c:-' -No ll~nn TW4-22 Let ':l~ Flow ,~ /) "88 No . Meter ., n Q -, • "· _ "7 "-No lrJ71:."I;' TW4-24 '71...1'-/-Flow ,~."' 'at No Meter , ~ t. o "'1. n "I "'1.1 "9a No IJ "7" I TW4-25 '"7~ Q/_ Flow I I. /_ Ya No Meter Ii" o :J. -i '-f 1'-<'11 , ~ No " l)q, « TW4-1 R /_ "7-:t Flow J lJ .« v.. No Meter '1 :'.2 rt , ~ ,., . "7 "8s No /)~,:< TW4-2 '1.!> ,, .. ; Flow I I,, t.. .._ No Meter "' " 7 7 'i"'c:r Q Ya No /10.1./ t:. TW4-11 an 1'11 Flow JI-K "911 No Meter ~11 ~"" Q Vies No /] 'T 'lo s:r TW4-21 9./J "2,Q Flow //.. .I!. "'98 No Meter :'l ~ .(';~~nw, <',., 'ie:I; No ln«1l;" TW4-37 7!1 Cl I Flow 1 'l n ~ No Meter , ., 1./J /.,-, ") 'am No " ng,::i.i:; TW4-39 .... ~-, Flow ,~.() ._ No Meter , ... i,q,~ '-' .._ No I '1Q I.{ t:" TW4-40 -,. I -y -, Flow I ti. /J 'e. No Meter "'~flq,,._Q_ ca 1 'as No ,-,o ~ ~ TW4-41 0.'!I '" Flow .t::. () .... No Meter ~" .s-7~. ,:.::, "9s No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): ----------------- • Depth is measured to the nearest 0.01 feet. Weekly Inspection Form Date ,_. t'i-siO ; f ~ystem Operational (lf,nci ,hote Tl me W II e Deot h* C ts b ommen an~ ero lams/corrective actlonsl nou1:r MW-4 srq '~ Flow J.-1 /') V.. No ,,., Meter ~ e: 7 ~ Q /_ '.:\ ~ t .. \a No t]q~r, MW-26" '2.&:'IQ Flow I IJ /,. ... No Meter '-/Sl ::i ~ u u. u --No 1,~r:; TW4-19 7-::J ~< Flow '7 /) .._ No Meter .:i. '1 n I q , n -, YIN No • 'n4n9. TW4-20 Ql),1'>7-Flow :::::t ,_, 'lfe5>,. No Meter ", ~ 1 ~ ~ , q ._,.No In (Jff. TW4-4 Q ,c:z .,. <"' Flow 14 Q .. .._. No Meter -rn,:; ~ ~ , "] ... No lnann TWN-2 ~4 '(~ Flow //-st 'Ult No Meter, ~nq !> r.. o a :-.. No I/JS( ~I;" TW4-22 -,,:, 1'7 Flow I '2 ~ ... No Meter ...,. , / r;-.:1 Q _ c ~ No IJ~'l"'T TW4-24 "'-q /,. :J Flow r1.~ .... No Meter , ~ IA J./ 4 /.. /l_ I'.. q )fa. No '1r11:~ TW4-25 "'7« ~o Flow Jf •. '-1 ~ No Meter 50 ggc;rn Lf4 l(D. No nQr:;n TW4-1 111"1.'.Jq Flow JI ~ ~ No Meter ~ !> ~ q ~ , . q \fa No ()Q::1,,Sir TW4-2 ,nc:. ~n Flow t,.O ~ No Meter ~~ c:il«n,. -:1, ,.._ No nq~.2 TW4-11 QfJ, r/J-1 Flow J~ -9. ._ No Meter ~ c, .::i 7 o e;-)ta. No I 11 7 I./ , TW4-21 -rn, I I Flow /t:. _ ~ 'lei No Meter ~ .., r-. ~ , , ~ ~ ~ ~ No "'q/} :J TW4-37 '7 ~ ct 4--...._ Elow J 'fl /) ¥!1:1 No Meter 1 7 ~ C" 1./ lJ o ., ~ No I/JOJw TW4-39 /,.Q ~ ,:;-Flow /9,_/) ._ No , Meter ~;q,;~~.4 ,._ No ,n·"J 11 TW4-40 ...,, ..,..., Flow l'R n 'ms. No Meter 4 "i 7 "' , "2 . .., u \fa No nqe::Q TW4-41 t;f LI J /;'" Flow LI_~ '* No Meter '!l. '1. .., n L/ 1 ... _ q"' -No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): ---------------- * Depth is measured to the nearest 0.01 feet. Weekly Inspection Form '. Ti W II Name :72.::cn (c~11110r1 ka::: f/,,«,~ Sysfum Operational (l;:ote D th* C ts bl I Date me e 8D ommen an]l 2ro ems correc11ve actions) nq,:r: MW-4 9.~nl.. Flow 4 LI \'-No ·' ~,,/_ Meter ::, ,;--, q , ~ 4:1. . 1 -=-._. No nQ'l. :> MW-26 t;l, f) "'1.4 Flow "· '.] Va No Meter 1./R 3 7~i:_ ~ ._ No "4t;' TW4-19 ..,. !I « '=I Flow J ~./1 . ... No Meter ~ !J 1 '1 ~ n a LI ¥a No /Jq:in TW4-20 I'.:~ I 'T Flow .'.'> Cit -No Meter 4 , , 1 , ., ""'-' 'm-No ,n,~ TW4-4 94 n ~ Flow J /.. 'l.. .... .._. No Meter 70/'.... 7/.. L . ..., -No lnQI~ TWN-2 r:a_ an Flow It':. -'I "9 No Meter 1 ~ 1 n ~ ~ c:.-, \fD No lnqns::/ TW4-22 "'11'-, ,., Flow 1« n )fa No Meter -, 1 ~ 4 -, J;r c-. ... No n4n::J TW4-24 .1':._Q ~-~ Flow I I'... i') 'MB No Meter , ':l /,. s:1 ~ /. /... <:> q ... No ns:11~ TW4-25 1!1 ..,, Flow JI ~ \lea No Meter ~ J e; 3 Sf '7. ~ ~ Ya No ,n ntf TW4-1 JIM,. ~la Flow J :l. n .... No Meter ~ 'l ct .r... , Sl _ I',. ...,. No : I/Jo1-1r1 TW4-2 J J ~. ,~ Flow Jr;._ n Ya No Meter 3aqq·71..J :::> "88--No 114-.1-1 n TW4-11 CU\ a~ Flow /~., ,;-Ya No Meter ~ ct·i-1 ~ ~ ~ ¥e No I 1Hl l>!J TW4-21 "7'/J /'....'ll. Flow /~.ii . Yes No Meter ~ !> .., ..-, r/-, ~ . n 41 .._. No lnq I LI TW4-37 , \. ~n Flow Hl. {) · \g No Meter , -, -rnn a-,_ t:::' ~ No nc, ':l ,_ TW4-39 /... 0 e: I;"' Flow J 12. () 'te6 No Meter rn~ ~ ".:l n1 •. Q 'ta No Jn:J.t:. TW4-40 -,,.gc;-Flow I 'R. l'1 ''a" No Meter ...;::;:.,·:; ":I_I'!. .'-.n .__ No J IJ I -.::J TW4-41 .. .:1 a nn Flow <. /,,. ~ No Meter ., (ii tfl ~ .., n. n II 'ml' No Operational Problems (Please list well number): Corrective Action(s) Taken (Please list well number): ---------------- * Depth is measured to the nearest 0.01 feet. Weekly Inspection Form I'.\ •• Date 4 _,,.9 .. AA Name:V«o ~--z;Q,m:: ,q'it/(,~,. · · : Svstem Operttnaf Clf>·no:note C t bl ii . Time e en· ommens an~ ero ems/correct(ve ctlons} W II D th* ,n:J.~ MW-4 QJ_ ~~ ... Flow "· () Va No ,.. . ~ Meter '.::> c: S1 t:. .., ~ '3 ~ e:-Yes> No Of.I'<~ MW-26 ~/ .... c::'n Flow I /'J ~ -No Meter 1,1 q e: "I t; Sl Q .... No JW/1':J TW4-19 7:::J.4~ Flow J 7. fl '*8 No I Meter -:, ~ ~ /... /_ ri /-, Va> No /Jq J.I () TW4-20 q"'-'~ Flow 3.~ )fall No Meter "'..1 ~ -, "" , . n ,:;-._ No I "':\ "I .;" TW4-4 f/7 C:4 Flow I~--'-' "" ~ No Meter 7fJ 7,t () '?. q _ -No I nQ I ':l TWN-2 Jlj'(4 () I Flow JI'~ ,J --No· Meter , "":a,~ t:. l'l ll· < ¥;a No l)q:,. I. TW4-22 ,: i;, 1./Q Flow JR 0 -No Meter -, , c-~ ~ .ti'. , -No lno1n TW4-24 /_..q_a.("' Flow ) 11 " :. No Meter , ~ ., ::, ., , -:i /-1_ ... No /'}qt)/.,. TW4-25 ct1 '.'11) Flow } 0."' 'test No Meter ~ ;i, 1 .:l _, .., . ":l. q 'l:es> No 1?i ~ n TW4-1 /n~ L "-Flow J ~ ,:;-"-No Meter 3-q.o 3 'f "J Q "89-No 1n I~ TW4-2 1/I o.Jn Flow-) 6. l:J \fejJ No ' Meter ~qnq ~ t; .11 -No ,nn,: TW4-11 QI J.ln Flow JI,,. I) ... No Meter lo q '5' h. ~ ~ 'ID No •,; nQnn TW4-21 ,~.~-I Flow J t. ., ~ No- Meter ,!) .1 Q I , ~ r u,;r Va, No - l)q-a.u TW4-37 -, t. (l /'_ Flow JR.n ~ No Meter .. ,-,-,'-' 7 mo_ 2. wa, No (JQLJ~ TW4-39 /_Q qq Flow i«.o ~ No Meter /.~~Iii :f.,, z::-v.. No I~ ,;'f!i TW4-40 "1 l • .., .,_ Flow J'it l'I ~ No Meter r; o 'J. ::i. :'.l ~ nq ~ No J ~ 2, { .. TW4-41 aft n~ Flow ~ .&;' -.. No Meter~ .:1 ca q r... ~ "-, q ~No Operational Problems (Please list well number}: Corrective Action(s) Taken (Please list well number): ---------------- .. Depth is measured to the nearest 0.01 feet. ® TW4-42 ¢5526 MW-38 "9-5463 estimated dry area temporary perched monitoring well installed April, 2019 showing elevation in feet amsl perched monitoring well installed February, 2018 showing elevation in feet amsl TW4-40 temporary perched monitoring well +5526 installed February, 2018 showing elevation in feet amsl M;';5s04 perched monitoring well showing elevation in feet amsl TW4-12 0 5569 temporary perched monitoring well showing elevation in feet amsl ~~~67 temporary perched nitrate monitoring V well showing elevation in feet amsl PIEZ-1 perched piezometer showing Q 5589 elevation in feet amsl RUIN SPRING c!, 5380 seep or spring showing elevation in feet amsl NOTES: MW-4, MW-26, TW4-1, TW4-2, TW4-4, TW4-11, TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are chloroform pumping wells; TW4-22, TW4-24, TW4-25 and TWN·2 are nitrate pumping wells; TW4-1,_TW4-2 and TW4-11 wate!__levels are below the base o_fthe Burro_C_~on Formation HYDRO GEO CHEM,INC. KRIGED 2nd QUARTER, 2020 WATER LEVELS WHITE MESA SITE APPROVED DATE REFERENCE H:n18000/aug20/WL/Uwl0620.srf FIGURE C-1 -, , I • @ TW4-42 ¢5526 MW-38 "¢-5463 estimated nitrate capture zone boundary stream tube resulting from pumping (note: capture for nitrate pumping wells TW4-22, TW4-24 and TW4-25 incorporated within capture of chloroform pumping system) estimated chloroform capture zone boundary stream tubes resulting from pumping. (note: combined capture shown for MW-4, TW4-1, TW4-2, TW4-4, TW4-11, TW4-40 and TW4-41; for MW-26, TW4-20 and TW4-37; and for TW4-19, TW4-21 and TW4-39) estimated dry area temporary perched monitoring well installed April, 2019 showing elevation in feet amsl perched monitoring well installed February, 2018 showing elevatlon in feet amsl TW4-40 temporary perched monitoring well +5526 installed February, 2018 showing elevation in feet amsl M;;~04 perched monitoring well showing elevation in feet amsl TW4-12 . 0 5569 temporary perched monitoring well showing elevation in feet amsl TWN-7 h d . . . .A.5567 temporary perc e nitrate monitoring V well showing elevation in feet amsl PIEZ-1 perched piezometer showing (ijj 5589 elevation in feet amsl RUIN SPRING b 5380 seep or spring showing elevation in feet amsl 1 mile NOTES: MW-4, MW-26, TW4-1, TW4-2, TW4-4, TW4-11, TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are chloroform pumping wells; TW4-22, TW4-24, TW4-25 and TWN-2 are nitrate pumping wells; 1'f,14-1, TW4-2 a_11d TW4-11 water levels are be_l<>w the base _o!__ the Burro Can~on Formation HYDRO GEO CHEM, INC. KRIGED 2nd QUARTER, 2020 WATER LEVELS AND ESTIMATED CAPTURE ZONES WHITE MESA SITE APPROVED DATE REFERENCE I FIGURE H:n18000/aug20/WL/Uwl0620NTcz2.srf I C-2 II TW4-42 ¢ 5526 TW4-40 ... 5526 MW-25 .5533 TW4-7 0 5533 estimated nitrate capture zone boundary stream tube resulting from pumping (note: capture for nitrate pumping wells TW4-22, TW4-24 and TW4-25 incorporated within capture of chloroform pumping system) estimated chloroform capture zone boundary stream tubes resulting from pumping. (note: combined capture shown for MW-4, TW4-1, TW4-2, TW4-4, TW4-11, TW4-40 and TW4-41; for MW-26, TW4-20 and TW4-37; and for TW4-19, TW4-21 and TW4-39) temporary perched monitoring well installed April, 2019 showing elevation in feet amsl temporary perched monitoring well installed February, 2018 showing elevation in feet amst perched monitoring well showing elevation in feet amst temporary perched monitoring well showing elevation in feet amst PIEZ-2 perched piezometer showing '-5585. elevation in feet amsl NOTES: MW-4, MW-26, TW4-1 , TW4-2, TW4-4, TW4-11, TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are chloroform pumping wells; TW4-22, TW4-24, TW4-25 and TWN-2 are nitrate pumping wells; TW4-1, TW4-2 and TW4-11 water levels are below the base of the Burro Canyon Formation HYDRO GEO CHEM, INC. APPROVED KRIGED 2nd QUARTER, 2020 WATER LEVELS AND ESTIMATED CAPTURE ZONES WHITE MESA SITE detail ma DATE REFERENCE FIGURE H :/718000/aug20/WL/Uwl0620NTcz.srf C-3 TabD Kriged Previous Quarter Groundwater Contour Map @ estimated dry area TW4-42 temporary perched monitoring well ¢ 5527 installed April, 2019 showing elevation in feet amsl MW-38 perched monitoring well -¢-5463 installed February, 2018 showing elevation in feet amsl TW4-40 temporary perched monitoring well +5526 installed February, 2018 showing elevation in feet amsl M;';5 504 perched monitoring well showing elevation in feet amsl TW4-12 . . 0 5570 temporary perched monitoring well showing elevation in feet amsl TWN-7 . . . <>5567 temporary perched nitrate monitoring well showing elevation in feet amsl PIEZ-1 perched piezometer showing '-l 5589 elevation in feet amsl RUIN SPRING 6 5380 seep or spring showing elevation in feet amsl NOTES: MW-4, MW-26, TW4-1, TW4-2, TW4-4, TW4-11, TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are chloroform pumping wells; TW4-22, TW4-24, TW4-25 and TWN-2 are nitrate pumping wells; TW4-1 , TW4-2 and TW4-11 water levels are below the base of the Burro Canyon Formation HYDRO GEO CHEM,INC. KRIGED 1st QUARTER, 2020 WATER LEVELS WHITE MESA SITE APPROVED DATE REFERENCE H:n18000/may20/WUUwl0320.srf FIGURE D-1 TabE Hydrographs of Groundwater Elevations over Time for Nitrate Monitoring Wells -Q. E .c = -a, E i= I., a, > 0 a, > a, .J I., a, -~ T"" I z ~ DG/8 ~/90 6~/vO~O L~/GG/60 9~/0~/90 v~/LG/G~ 8~/v~/BO G~/W/170 60/90/LO 80/GG/GO 0 c:i 0 c:i T"" 0 c:i C\J 0 c:i C') 0 c:i """ ' 1 •• j 0 c:i LO ' • ' t ~ ' 0 c:i (0 (·u) 1u1od 6u1Jnseaw Mo1ae 1.11daa r J 0 ' • • ' i j ·~ 0 0 c:i (X) OG/8~/90 6~/vO/cO -L ~/GG/60 Q. E -.c = -9~/0~/90 Cl) E i= ... Cl) > 0 v~/LG/G~ Cl) > Cl) .J ... Cl) 8~!v~1so -(U 3: C\I I z ~ UHO/vO 60/90/LO 0 c:i 0 c:i ..... C! 0 N 0 g 0 c:i ~ 0 c:i I() 0 c:i CD 0 R 0 c:i co Ol/8~/90 6 ~/t,0/lO -L~!Cl/60 Q. E .Q ..: --9~/0~/SO G) E i= ... G) > 0 t, ~/LG/G ~ G) > G) ..J ... G) £ ~/t,~/80 -~ M I z ~ G ~/~O/t,O 60/90/LO 0 ci q I{) 0 ci ,.... C! I{) ,.... 0 ci (\J q I{) C\J 0 ci ('I) 0 ci "St" ""' 0 0 O> 0 0 Depth Below Measuring Point (ft.) 01 0 0 .j:. 0 0 w 0 0 I\) 0 0 ..... 0 0 0 0 1------1-----l-----+----------------02/22/08 07/06/09 11/18/10 04/01/12 08/14/13 12/27/14 05/10/16 09/22/17 02/04/19 06/18/20 L_ __ _L ___ J_ __ _.1.. ___ ...J...._ __ ----'------'------10/31/21 ~ z I .,::. i -(I) "'I ,... (I) < (I) 0 < (I) "'I ::t 3 (I) -? C" 3 "O - <O 0 0 (X) 0 0 ~ t • 0 i • ~ •• • •• 0 • j ' • • •• • . • 0 • 0 •• • 1, 10 - ,..... • • • • • •• • • • • ~ • Depth Below Measuring Point (ft.) -...J 0 0 ---~ O> 0 0 = - c.n 0 0 ""' 0 0 (,) 0 0 I\) 0 0 _. 0 0 0 0 02/22/08 07/06/09 11/18/10 04/01/12 08/14/13 12/27/14 05/10/16 09/22/17 02/04/19 06/18/20 10/31/21 ~ z I 0) :e m -CD ""I r-CD < CD 0 < CD ""I ::! 3 CD ---. er 3 't, - -Q. E .c = -C1) E i= I., C1) > 0 C1) > C1) .J I., C1) -~ r,.. I z ~ OC::/B~/90 6~/t>O/C::O L~/C::C::/60 9~/0~/SO t>~/LG/C::~ £~/t>~/80 UHO/t>O 60/90/LO 0 ci 00 0 C\i 00 0 ~ O> 0 o:i O> Depth Below Measuring Point {ft.) 0) 0) 0) 0) 0) 0) 0) 0) 0) 01 01 .i,.. w w [') I\J _. _. 0 0 co co 6 01 6 01 i::> 01 6 01 6 01 6 02/22/08 07/06/09 11/18/10 04/01/12 ~ z I .... ,1::1, 08/14/13 ~ -(I) "'I r (I) < 12/27/14 !. 0 < (I) "'I ::! 05/10/16 3 (I) -? 2: 3 09/22/17 "C - 02/04/19 06/18/20 .__ _ __._ __ ..__ _ __._ __ .....__ __________ ~-~--~-~ 10/31/21 ~ <O CJ'I ~ <O 0 Depth Below Measuring Point (ft.) ~ CX> CJ'I ~ CX> 0 ~ """ CJ'I ~ :-..i 0 ~ 0) CJ'I t------1-------------+------+-----+------+ 02/22/08 07/06/09 11/18/10 04/01/12 08/14/13 12/27/14 05/10/16 09/22/17 02/04/19 06/18/20 ,___ ___ ......_ ___ _._ ___ __. ____ ...,__ ___ _._ ___ __._ 10/31/21 ~ z I ...... en :e m .... CD .., r-CD < !. 0 < CD .., ::t 3 CD --.... . C" -3 "C - ....... 0 0 C1) 0 0 I~ ~ Depth Below Measuring Point (ft.) 01 0 0 ~ 0 0 (,.) 0 0 I\) 0 0 ~----~ • 0 • 0 l •• • • • ~ ~ • ' ' ~ • • • • • • 0 0 ~ . ~ • • •• l .... 0 0 0 0 02/22/08 07/06/09 11/18/10 04/01/12 08/14/13 12/27/14 05/10/16 09/22/17 02/04/19 06/18/20 10/31/21 ~ z I ..... Cl) :e m -C1) ., r C1) < !. 0 < C1) ., ::t 3 C1) -? C" -3 "C - C1I 0) 0 C1I C1I 0 Depth Below Measuring Point (ft.) C1I .i:,. 0 C1I w 0 C1I I\) 0 C1I ..... 0 C1I 0 0 .i:,. co 0 -------+--------+----------------02/22/08 07/06/09 11/18/10 04/01/12 08/14/13 12/27/14 05/10/16 09/22/17 02/04/19 06/18/20 '---~---_.._ ___ .__ __ __._ ___ __._ ___ .,__ __ __,_ 10/31/21 ~ z I ..... <D ~ -(I) "'I r (I) < (I) -0 < (I) "'I ::! 3 (I) -= . C' -3 "'C - -a. E -..c = -Cl) E i= I-Cl) > 0 -Cl) > Cl) .J I-Cl) -~ 0 C") I 3: :E Ol/8~/90 L~/Gl/60 17~/LG/G~ l~/W/170 60/90/LO 90/0~/0~ 0 I() I'- 0 aj I'- (·») IU!Od 6u1Jnseaw Mo1ae 41daa ~ 0 CX) CXl I\) CXl 0 Depth Below Measuring Point (ft.) ....... ....... 0) ....... .i,. ....... 0 0) 0) 6 6 6 ....... f') 0 6 0) CXl 6 6 1---+-----+----t----+----1---+-----+-----t-01/14/04 6 5X> 0 10/10/06 07/06/09 04/01/12 12/27/14 09/22/17 06/18/20 ......_ __ .___ _ ____. __ ___. __ ___. __ __._ __ ___._ __ __._ __ _._ 03/15/23 s: =e I w ...... i -C1) ... r C1) < C1) -0 < C1) ... ::! 3 C1) -? 2: 3 "C - TabF Depths to Groundwater and Elevations over Time for Nitrate Monitoring Wells Water Levels and Data over Time White Mesa Mill -Well TWN-1 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,646.96 5,648.09 1.13 106.13 5,600.38 02/06/09 47.71 46.58 5,599.99 07/21/09 48.10 46.97 5,600.26 09/21/09 47.83 46.70 5,601.10 10/28/09 46.99 45.86 5,602.59 12/14/09 45.50 44.37 5,600.55 03/11/10 47.54 46.41 5,600.66 05/11/10 47.43 46.30 5,599.18 09/29/10 48.91 47.78 5,598.92 12/21/10 49.17 48.04 5,598.29 02/28/11 49.80 48.67 5,597.80 06/21/11 50.29 49.16 5,597.32 09/20/11 50.77 49.64 5,597.15 12/21/11 50.94 49.81 5,596.54 03/27/12 51.55 50.42 5,596.52 06/28/12 51.57 50.44 5,595.03 09/27/12 53.06 51.93 5,596.62 12/28/12 51.47 50.34 5,593.54 03/28/13 54.55 53.42 5,592.38 06/27/13 55.71 54.58 5,591.65 09/27/13 56.44 55.31 5,590.34 12/20/13 57.75 56.62 5,590.03 03/27/14 58.06 56.93 5,589.09 06/25/14 59.00 57.87 5,588.15 09/25/14 59.94 58.81 5,587.74 12/17/14 60.35 59.22 5,587.09 03/26/15 61.00 59.87 5,586.79 06/22/15 61.30 60.17 5,586.39 09/30/15 61.70 60.57 5,586.05 12/02/15 62.04 60.91 5,585.89 03/30/16 62.20 61.07 5,585.30 06/30/16 62.79 61.66 5,584.95 09/29/16 63.14 62.01 5,584.55 12/21/16 63.54 62.41 5,584.74 03/30/17 63.35 62.22 5,584.29 06/27/17 63.80 62.67 5,583.77 09/26/17 64.32 63.19 5,583.44 11/29/17 64.65 63.52 5,583.03 03/29/18 65.06 63.93 5,582.79 06/22/18 65.30 64.17 5,582.22 09/26/18 65.87 64.74 5,582.14 12/17/18 65.95 64.82 5,581.49 03/26/19 66.60 65.47 5,581.18 06/24/19 66.91 65.78 5,581.12 08/13/19 66.97 65.84 5,580.93 11/19/19 67.16 66.03 5,580.54 02/13/20 67.55 66.42 Water Levels and Data over Time White Mesa Mill -Well TWN-2 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,625.75 5,626.69 0.94 95.9 5,611.37 2/6/09 15.32 14.38 5,610.63 7/21/09 16.06 15.12 5,609.73 9/21/09 16.96 16.02 5,607.08 11/2/09 19.61 18.67 5,606.57 12/14/09 20.12 19.18 5,612.45 3/11/10 14.24 13.30 5,612.78 5/11/10 13.91 12.97 5,611.37 9/29/10 15.32 14.38 5,610.24 12/21/10 16.45 15.51 5,610.64 2/28/11 16.05 15.11 5,609.78 6/21/11 16.91 15.97 5609.79 9/20/11 16.90 15.96 5609.72 12/21/11 16.97 16.03 5,605.69 3/27/12 21.00 20.06 5,605.67 6/28/12 21.02 20.08 5,603.03 9/27/12 23.66 22.72 5,605.76 12/28/12 20.93 19.99 5,598.28 3/28/13 28.41 27.47 5,594.32 6/27/13 32.37 31.43 5,594.38 9/27/13 32.31 31.37 5,594.68 12/20/13 32.01 31.07 5,597.79 3/27/14 28.90 27.96 5,595.80 6/25/14 30.89 29.95 5,587.67 9/25/14 39.02 38.08 5,592.66 12/17/14 34.03 33.09 5,596.71 3/26/15 29.98 29.04 5,598.64 6/22/15 28.05 27.11 5,597.89 9/30/15 28.80 27.86 5,597.89 12/2/15 28.80 27.86 5,594.25 3/30/16 32.44 31.50 5,590.26 6/30/16 36.43 35.49 5,591.67 9/29/16 35.02 34.08 5592.92 12/21/16 33.77 32.83 5589.05 3/30/17 37.64 36.7 5589.69 6/27/17 37.00 36.06 5590.71 9/26/17 35.98 35.04 5591.65 11/30/17 35.04 34.10 5574.69 3/28/18 52.00 51.06 5586.49 6/22/18 40.20 39.26 5550.31 9/24/18 76.38 75.44 5568.32 12/17/18 58.37 57.43 5553.52 3/25/19 73.17 72.23 5569.06 6/24/19 57.63 56.69 5565.38 8/12/19 61.31 60.37 5567.87 11/18/19 58.82 57.88 5577.69 2/13/20 49.00 48.06 Water Levels and Data over Time White Mesa Mill -Well TWN-2 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (L D) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,625.75 5,626.69 0.94 95.9 5566.89 5/5/20 59.80 58.86 Water Levels and Data over Time White Mesa Mill-Well TWN-3 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,633.64 5,634.50 0.86 96 5,603.77 2/6/09 30.73 29.87 5,602.37 7/21/09 32.13 31.27 5,602.34 9/21/09 32.16 31.30 5,602.60 10/28/09 31.90 31.04 5,603.12 12/14/09 31.38 30.52 5,602.90 3/11/10 31.60 30.74 5,603.23 5/11/10 31.27 30.41 5,602.86 9/29/10 31.64 30.78 5,603.35 12/21/10 31.15 30.29 5,602.89 2/28/11 31.61 30.75 5,602.75 6/21/11 31.75 30.89 5,602.40 9/20/11 32.10 31.24 5,602.40 12/21/11 32.10 31.24 5,601.70 3/27/12 32.80 31.94 5,601.67 6/28/12 32.83 31.97 5,600.50 9/27/12 34.00 33.14 5,601.74 12/28/12 32.76 31.90 5,598.60 3/28/13 35.90 35.04 5,597.18 6/27/13 37.32 36.46 5,597.36 9/27/13 37.14 36.28 5,597.60 12/20/13 36.90 36.04 5,598.00 3/27/14 36.50 35.64 5,596.34 6/25/14 38.16 37.30 5,596.30 9/25/14 38.20 37.34 5,596.55 12/17/14 37.95 37.09 5,596.20 3/26/15 38.30 37.44 5,596.00 6/22/15 38.50 37.64 5,596.61 9/30/15 37.89 37.03 5,596.09 12/2/15 38.41 37.55 5,595.29 3/30/16 39.21 38.35 5,594.61 6/30/16 39.89 39.03 5,593.79 9/29/16 40.71 39.85 5,594.20 12/21/16 40.30 39.44 5,594.20 3/30/17 40.30 39.44 5,592.85 6/27/17 41.65 40.79 5,592.60 9/26/17 41.90 41.04 5,593.33 11/29/17 41.17 40.31 5,592.55 3/29/18 41.95 41.09 5,592.45 6/22/18 42.05 41.19 5,592.90 9/26/18 41.60 40.74 5,594.29 12/18/18 40.21 39.35 5,591.99 3/26/19 42.51 41.65 5,592.69 6/24/19 41.81 40.95 5,592.50 8/13/19 42.00 41.14 5,592.78 11/19/19 41.72 40.86 5,592.33 2/13/20 42.17 41.31 Water Levels and Data over Time White Mesa Mill -Well TWN-3 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,591.78 5/5/20 42.72 41.86 Water Levels and Data over Time White Mesa Mill -Well TWN-4 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,641.04 5,641.87 0.83 126.4 5,601.47 2/6/09 40.40 39.57 5,604.26 7/21/09 37.61 36.78 5,605.02 9/21/09 36.85 36.02 5,605.87 10/28/09 36.00 35.17 5,605.81 12/14/09 36.06 35.23 5,605.31 3/11/10 36.56 35.73 5,605.36 5/11/10 36.51 35.68 5,604.59 9/29/10 37.28 36.45 5,604.42 12/21/10 37.45 36.62 5,603.69 2/28/11 38.18 37.35 5,603.36 6/21/11 38.51 37.68 5,602.82 9/20/11 39.05 38.22 5,602.79 12/21/11 39.08 38.25 5,600.82 3/27/12 41.05 40.22 5,600.84 6/28/12 41.03 40.20 5,598.47 9/27/12 43.40 42.57 5,600.86 12/28/12 41.01 40.18 5,595.57 3/28/13 46.30 45.47 5,594.12 6/27/13 47.75 46.92 5,593.33 9/27/13 48.54 47.71 5,591.92 12/20/13 49.95 49.12 5,591.85 3/27/14 50.02 49.19 5,590.49 6/25/14 51.38 50.55 5,589.64 9/25/14 52.23 51.40 5,589.42 12/17/14 52.45 51.62 5,589.17 3/26/15 52.70 51.87 5,588.17 6/22/15 53.70 52.87 5,587.48 9/30/15 54.39 53.56 5,587.02 12/2/15 54.85 54.02 5,586.90 3/20/16 54.97 54.14 5,586.18 6/30/16 55.69 54.86 5,585.72 9/29/16 56.15 55.32 5585.42 12/21/16 56.45 55.62 5586.35 3/30/17 55.52 54.69 5585.09 6/27/17 56.78 55.95 5584.41 9/26/17 57.46 56.63 5584.07 11/29/17 57.80 56.97 5583.76 3/29/18 58.11 57.28 5583.47 6/22/18 58.40 57.57 5582.92 9/26/18 58.95 58.12 5582.66 12/18/18 59.21 58.38 5582.23 3/26/19 59.64 58.81 5581.97 6/24/19 59.90 59.07 5581.96 8/13/19 59.91 59.08 5581.68 11/19/19 60.19 59.36 5581.34 2/13/20 60.53 59.70 Water Levels and Data over Time White Mesa Mill -Well TWN-4 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,641.04 5,641.87 0.83 126.4 5580.99 5/5/20 60.88 60.05 Water Levels and Data over Time White Mesa Mill -Well TWN-6 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,663.03 5,664.94 1.91 131.91 5,589.52 8/25/09 75.42 73.51 5,589.46 9/22/09 75.48 73.57 5,589.61 11/3/09 75.33 73.42 5,589.92 12/14/09 75.02 73.11 5,590.24 3/11/10 74.70 72.79 5,590.40 5/11/10 74.54 72.63 5,590.24 9/29/10 74.70 72.79 5,590.49 12/21/10 74.45 72.54 5,590.16 2/28/11 74.78 72.87 5,590.44 6/21/11 74.50 72.59 5,590.35 9/20/11 74.59 72.68 5,590.67 12/21/11 74.27 72.36 5,590.34 3/27/12 74.60 72.69 5,590.32 6/28/12 74.62 72.71 5,589.77 9/27/12 75.17 73.26 5,589.67 12/28/12 75.27 73.36 5,589.45 3/28/13 75.49 73.58 5,589.01 6/27/13 75.93 74.02 5,588.99 9/27/13 75.95 74.04 5,588.15 12/20/13 76.79 74.88 5,588.50 3/27/14 76.44 74.53 5,588.03 6/25/14 76.91 75.00 5,587.74 9/25/14 77.20 75.29 5,587.69 12/17/14 77.25 75.34 5,587.29 3/26/15 77.65 75.74 5,587.04 6/22/15 77.90 75.99 5,586.93 9/30/15 78.01 76.10 5,586.72 12/2/15 78.22 76.31 5,586.92 3/30/16 78.02 76.11 5,586.32 6/30/16 78.62 76.71 5,586.16 9/29/16 78.78 76.87 5,586.03 12/21/16 78.91 77.00 5,586.40 3/30/17 78.54 76.63 5,605.99 6/27/17 58.95 57.04 5585.76 9/26/17 79.18 77.27 5585.59 11/29/17 79.35 77.44 5585.63 3/29/18 79.31 77.4 5585.59 6/22/18 79.35 77.44 5585.26 9/26/18 79.68 77.77 5585.27 12/18/18 79.67 77.76 5585.16 3/26/19 79.78 77.87 5585.05 6/24/19 79.89 77.98 5584.86 8/13/19 80.08 78.17 5585.14 11/19/19 79.80 77.89 5584.92 2/13/20 80.02 78.11 5585.27 5/5/20 79.67 77.76 Water Levels and Data over Time White Mesa Mill -Well TWN-7 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,647.39 5,649.26 1.87 107.2 5,552.56 08/25/09 96.70 94.83 5,558.34 09/21/09 90.92 89.05 5,558.82 11/10/09 90.44 88.57 5,558.96 12/14/09 90.30 88.43 5,559.54 03/11/10 89.72 87.85 5,559.60 05/11/10 89.66 87.79 5,559.83 09/29/10 89.43 87.56 5,559.00 12/21/10 90.26 88.39 5,559.68 02/28/11 89.58 87.71 5,560.43 06/21/11 88.83 86.96 5,560.46 09/20/11 88.80 86.93 5,560.78 12/21/11 88.48 86.61 5,560.92 03/27/12 88.34 86.47 5,560.87 06/28/12 88.39 86.52 5,561.40 09/27/12 87.86 85.99 5,561.50 12/28/12 87.76 85.89 5,562.01 03/28/13 87.25 85.38 5,562.21 06/27/13 87.05 85.18 5,562.41 09/27/13 86.85 84.98 5,562.23 12/20/13 87.03 85.16 5,562.85 03/27/14 86.41 84.54 5,562.95 06/25/14 86.31 84.44 5,563.06 09/25/14 86.20 84.33 5,563.21 12/17/14 86.05 84.18 5,563.33 03/26/15 85.93 84.06 5,563.46 06/22/15 85.80 83.93 5,563.64 09/30/15 85.62 83.75 5,563.88 12/02/15 85.38 83.51 5,564.19 03/30/16 85.07 83.20 5,563.97 06/30/16 85.29 83.42 5,564.21 09/29/16 85.05 83.18 5,564.46 12/21/16 84.80 82.93 5,564.96 03/30/17 84.30 82.43 5,564.81 06/27/17 84.45 82.58 5,565.46 09/26/17 83.80 81.93 5,565.45 11/29/17 83.81 81.94 5,566.11 03/29/18 83.15 81.28 5,566.21 06/22/18 83.05 81.18 5,566.42 09/26/18 82.84 80.97 5,566.09 12/18/18 83.17 81.30 5,566.67 03/26/19 82.59 80.72 5,566.93 06/24/19 82.33 80.46 5,567.28 08/13/19 81.98 80.11 5,567.26 11/19/19 82.00 80.13 5,567.12 02/13/20 82.14 80.27 5,567.14 05/05/20 82.12 80.25 Water Levels and Data over Time White Mesa Mill -Well TWN-14 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5, 47.80 5,649.53 1.73 124.73 5,586.18 11/4/09 63.35 61.62 5,586.51 12/14/09 63.02 61.29 5,586.71 3/11/10 62.82 61.09 5,586.72 5/11/10 62.81 61.08 5,586.53 9/29/10 63.00 61.27 5,586.80 12/21/10 62.73 61.00 5,586.74 2/28/11 62.79 61.06 5,586.84 6/21/11 62.69 60.96 5,586.73 9/20/11 62.80 61.07 5,586.98 12/21/11 62.55 60.82 5,587.07 3/27/12 62.46 60.73 5,587.10 6/28/12 62.43 60.70 5,587.07 9/27/12 62.46 60.73 5,587.33 12/28/12 62.20 60.47 5,587.43 3/28/13 62.10 60.37 5,587.43 6/27/13 62.10 60.37 5,587.72 9/27/13 61.81 60.08 5,587.22 12/20/13 62.31 60.58 5,587.91 3/27/14 61.62 59.89 5,587.74 6/25/14 61.79 60.06 5,587.76 9/25/14 61.77 60.04 5,587.88 12/17/14 61.65 59.92 5,587.97 3/26/15 61.56 59.83 5,587.98 6/22/15 61.55 59.82 5,588.18 9/30/15 61.35 59.62 5,588.23 12/2/15 61.30 59.57 5,588.70 3/30/16 60.83 59.10 5,588.31 6/30/16 61.22 59.49 5,588.36 9/29/16 61.17 59.44 5,588.43 12/21/16 61.10 59.37 5,588.96 3/30/17 60.57 58.84 5,589.07 6/27/17 60.46 58.73 5588.86 9/26/17 60.67 58.94 5588.82 11/29/17 60.71 58.98 5589.12 3/29/18 60.41 58.68 5589.19 6/22/18 60.34 58.61 5589.12 9/26/18 60.41 58.68 5589.20 12/18/18 60.33 58.60 5589.32 3/26/19 60.21 58.48 5589.40 6/25/19 60.13 58.40 5589.32 8/13/19 60.21 58.48 5589.59 11/19/19 59.94 58.21 5589.73 2/13/20 59.80 58.07 5590.17 5/5/20 59.36 57.63 Water Levels and Data over Time White Mesa Mill -Well TWN-16 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5 651.07 5 652.70 1.63 94.63 5,603.34 11/4/09 49.36 47.73 5,603.56 12/14/09 49.14 47.51 5,603.84 3/11/10 48.86 47.23 5,604.31 5/11/10 48.39 46.76 5,604.28 9/29/10 48.42 46.79 5,604.39 12/21/10 48.31 46.68 5,604.20 2/28/11 48.50 46.87 5,604.55 6/21/11 48.15 46.52 5,604.74 9/20/11 47.96 46.33 5,604.94 12/21/11 47.76 46.13 5,604.84 3/27/12 47.86 46.23 5,604.85 6/28/12 47.85 46.22 5,604.99 9/27/12 47.71 46.08 5,605.10 12/28/12 47.60 45.97 5,605.22 3/28/13 47.48 45.85 5,605.11 6/27/13 47.59 45.96 5,605.39 9/27/13 47.31 45.68 5,604.99 12/20/13 47.71 46.08 5,605.71 3/27/14 46.99 45.36 5,605.16 6/25/14 47.54 45.91 5,605.10 9/25/14 47.60 45.97 5,605.25 12/17/14 47.45 45.82 5,605.04 3/26/15 47.66 46.03 5,604.99 6/22/15 47.71 46.08 5,605.05 9/30/15 47.65 46.02 5,604.96 12/2/15 47.74 46.11 5,605.25 3/30/16 47.45 45.82 5,605.00 6/30/16 47.70 46.07 5,605.00 9/29/16 47.70 46.07 5,605.00 12/21/16 47.70 46.07 5,605.43 3/30/17 47.27 45.64 5,605.20 6/27/17 47.50 45.87 5605.00 9/26/17 47.70 46.07 5605.02 11/29/17 47.68 46.05 5605.11 3/29/18 47.59 45.96 5605.19 6/22/18 47.51 45.88 5604.99 9/26/18 47.71 46.08 5605.18 12/19/18 47.52 45.89 5605.06 3/26/19 47.64 46.01 5604.96 6/24/19 47.74 46.11 5604.87 8/13/19 47.83 46.20 5605.19 11/19/19 47.51 45.88 5605.02 2/13/20 47.68 46.05 5605.3 5/5/20 47.40 45.77 Water Levels and Data over Time White Mesa Mill -Well TWN -18 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,643.95 5,645.45 1.50 147 5,586.85 11/2/09 58.60 57.10 5,600.14 12/14/09 45.31 43.81 5,587.36 3/11/10 58.09 56.59 5,587.71 5/11/10 57.74 56.24 5,587.50 9/29/10 57.95 56.45 5,607.66 12/21/10 37.79 36.29 5,587.35 2/28/11 58.10 56.60 5,587.71 6/21/11 57.74 56.24 5,587.65 9/20/11 57.80 56.30 5,587.95 12/21/11 57.50 56.00 5,587.05 3/27/12 58.40 56.90 5,587.05 6/28/12 58.40 56.90 5,587.50 9/27/12 57.95 56.45 5,587.50 12/28/12 57.95 56.45 5,587.32 3/28/13 58.13 56.63 5,586.95 6/27/13 58.50 57.00 5,587.02 9/27/13 58.43 56.93 5,586.26 12/20/13 59.19 57.69 5,586.87 3/27/14 58.58 57.08 5,586.23 6/25/14 59.22 57.72 5,586.02 9/25/14 59.43 57.93 5,585.99 12/17/14 59.46 57.96 5,585.66 3/26/15 59.79 58.29 5,585.45 6/22/15 60.00 58.50 5,585.37 9/30/15 60.08 58.58 5,585.24 12/2/15 60.21 58.71 5,585.38 3/30/16 60.07 58.57 5,584.85 6/30/16 60.60 59.10 5,584.69 9/29/16 60.76 59.26 5,584.60 12/21/16 60.85 59.35 5,584.99 3/30/17 60.46 58.96 5,584.65 6/27/17 60.80 59.30 5584.36 9/26/17 61.09 59.59 5584.24 11/29/17 61.21 59.71 5584.25 3/29/18 61.20 59.70 5584.23 6/22/18 61.22 59.72 5583.92 9/26/18 61.53 60.03 5583.85 12/18/18 61.60 60.10 5583.72 3/26/19 61.73 60.23 5583.69 6/24/19 61.76 60.26 5583.76 8/13/19 61.69 60.19 5583.72 11/19/19 61.73 60.23 5583.54 2/13/20 61.91 60.41 5583.34 5/5/20 62.11 60.61 Water Levels and Data over Time White Mesa Mill -Well TWN-19 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5 659.59 5,661.36 1.77 107.77 5,606.17 11/2/09 55.19 53.42 5,606.70 12/14/09 54.66 52.89 5,607.22 3/11/10 54.14 52.37 5,607.89 5/11/10 53.47 51.70 5,607.98 9/29/10 53.38 51.61 5,608.41 12/21/10 52.95 51.18 5,608.49 2/28/11 52.87 51.10 5,608.60 6/21/11 52.76 50.99 5,609.17 9/20/11 52.19 50.42 5,608.90 12/21/11 52.46 50.69 5,608.87 3/27/12 52.49 50.72 5,608.86 6/28/12 52.50 50.73 5,608.86 9/27/12 52.50 50.73 5,608.86 12/28/12 52.50 50.73 5,609.17 3/28/13 52.19 50.42 5,608.88 6/27/13 52.48 50.71 5,608.92 9/27/13 52.44 50.67 5,608.46 12/20/13 52.90 51.13 5,608.88 3/27/14 52.48 50.71 5,608.33 6/25/14 53.03 51.26 5,608.11 9/25/14 53.25 51.48 5,608.36 12/17/14 53.00 51.23 5,607.96 3/26/15 53.40 51.63 5,607.98 6/22/15 53.38 51.61 5,608.06 9/30/15 53.30 51.53 5,607.88 12/2/15 53.48 51.71 5,608.41 3/30/16 52.95 51.18 5,611.39 6/30/16 49.97 48.20 5,607.90 9/29/16 53.46 51.69 5,608.07 12/21/16 53.29 51.52 5,608.44 3/30/17 52.92 51.15 5,608.07 6/27/17 53.29 51.52 5608.06 9/26/17 53.30 51.53 5607.91 11/29/17 53.45 51.68 5608.00 3/28/18 53.36 51.59 5607.71 6/21/18 53.65 51.88 5607.50 9/26/18 53.86 52.09 5607.94 12/19/18 53.42 51.65 5607.42 3/26/19 53.94 52.17 5607.46 6/25/19 53.90 52.13 5607.39 8/13/19 53.97 52.20 5607.84 11/19/19 53.52 51.75 5607.69 2/13/20 53.67 51.90 5607.57 5/5/20 53.79 52.02 Water Levels and Data over Time White Mesa Mill-Well MW-30 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of Date Of Water Water Depth Of (WL) (LSD) (MP) Riser (L) Monitoring (blw.MP) (blw.LSD) Well 5,613.34 5.614.50 l.16 110 5,534.92 I 0/24/06 79.58 78.42 5,535.09 3/16/07 79.41 78.25 5,535.46 8/27/07 79.04 77.88 5,535.06 10/15/07 79.44 78.28 5,535.78 3/15/08 78.72 77.56 5,536.26 6/15/08 78.24 77.08 5,536.35 9/15/08 78.15 76.99 5,536.68 11/15/08 77.82 76.66 5,535.42 3/15/09 79.08 77.92 5,537.11 6/30/09 77.39 76.23 5,536.93 9110/09 77.57 76.41 5,537.23 12/11/09 77.27 76.11 5,537.59 3/11/10 76.91 75.75 5,537.85 5/11/10 76.65 75.49 5,538.37 9/29/10 76.13 74.97 5,537.70 12/21/10 76.8 75.64 5,537.67 2/28/11 76.83 75.67 5,538.31 6/21/11 76.19 75.03 5,538.15 9/20/11 76.35 75.19 5,538.42 12/21/11 76.08 74.92 5,538.54 3/27/12 75.96 74.8 5,538.60 6/28/12 75.9 74.74 5,538.68 9/27/1 2 75.82 74.66 5,538.99 12/28/12 75.51 74.35 5,539.25 3/28/13 75.25 74.09 5,539.05 6/27/13 75.45 74.29 5,539.60 9/27/13 74.90 73.74 5,539.67 12/20/13 74.83 73.67 5,539.77 3/27/14 74.73 73.57 5,539.40 6/25/14 75.10 73.94 5,539.19 9/25/14 75.31 74.15 5,539.30 12/17/14 75.20 74.04 5,539.01 3/26/15 75.49 74.33 5,538.99 6/22/15 75.51 74.35 5,539.10 9/30/15 75.40 74.24 5,538.90 12/2/15 75.60 74.44 5,539.53 3/30/16 74.97 73.81 5,539.11 6/30/16 75.39 74.23 5,539.05 9/29/16 75.45 74.29 5,539.06 12/21/16 75.44 74.28 5,539.81 3/30/17 74.69 73.53 5,539.60 6/27/17 74.90 73.74 5539.40 9/27/17 75.10 73.94 5539.30 11/30/17 75.20 74.04 5539.55 3/29/18 74.95 73.79 5539.63 6/22/18 74.87 73.71 5539.40 9/26/18 75.10 73.94 5539.59 12/17/18 74.91 73.75 5539.42 3/26/19 75.08 73.92 5539.70 6/24/19 74.80 73.64 5539.45 8/13/19 75.05 73.89 5539.53 11/19/19 74.97 73.81 5539.57 2/13/20 74.93 73.77 Water Levels and Data over Time White Mesa Mill -Well MW-31 Total or Measuring Measured Total Water Land Point Depth to Depth to Total Elevation Surface Elevation Length Of' Date Of Water Water Depth Of (WL) (LSD (MP) Riser (L) Monitoring (bhv.MP) (blw.LSD) Well 5,615.26 5,616.40 1.14 130 5,544.07 10/24/06 72.33 71.19 5,544.45 3/16/07 71.95 70.81 5,536.94 8/27/07 79.46 78.32 5,544.62 10/15/07 71.78 70.64 5,545.37 3/15/08 71.03 69.89 5,544.50 6/15/08 71.90 70.76 5,545.94 9/15/08 70.46 69.32 5,546.42 11/15/08 69.98 68.84 5,546.03 3/15/09 70.37 69.23 5,546.65 6/30/09 69.75 68.61 5,546.45 9/10/09 69.95 68.81 5,546.75 12/11/09 69.65 68.51 5,547.09 3/11/10 69.31 68.17 5,547.41 5/11/10 68.99 67.85 5,547.28 9/29/10 69.12 67.98 5,547.45 12/21/10 68.95 67.81 5,547.37 2/28/11 69.03 67.89 5,547.96 6/21/11 68.44 67.3 5,547.65 9/20/11 68.75 67.61 5,548.34 12/21/11 68.06 66.92 5,548.30 3/27/12 68.10 66.96 5,548.40 6/28/12 68.00 66.86 5,548.59 9/27/12 67.81 66.67 5,548.91 12/28/12 67.49 66.35 5,549.14 3/28/13 67.26 66.12 5,548.90 6/27/13 67.50 66.36 5,549.25 9/27/13 67.15 66.01 5,549.16 12/20/13 67.24 66.10 5,548.95 3/27/14 67.45 66.31 5,548.60 6/25/14 67.80 66.66 5,548.19 9/25/14 68.21 67.07 5,548.25 12/17/14 68.15 67.01 5,548.14 3/26/15 68.26 67.12 5,547.85 6/22/15 68.55 67.41 5,548.00 9/30/15 68.40 67.26 5,547.84 12/2/15 68.56 67.42 5,548.35 3/30/16 68.05 66.91 5,548.00 6/30/16 68.40 67.26 5,547.80 9/29/16 68.60 67.46 5,547.80 12/21/16 68.60 67.46 5,548.30 3/30/17 68.10 66.96 5,548.10 6/27/17 68.30 67.16 5,547.93 9/27/17 68.47 67.33 5,547.80 11/30/17 68.60 67.46 5,547.92 3/29/18 68.48 67.34 5,547.95 6/22/18 68.45 67.31 5,547.69 9/26/18 68.71 67.57 5,547.82 12/17/18 68.58 67.44 5,547.56 3/26/19 68.84 67.70 5,547.68 6/24/19 68.72 67.58 5,547.56 8/13/19 68.84 67.70 5,547.58 11/19/19 68.82 67.68 5,547.59 2/13/20 68.81 67.67 5,547.92 5/5/20 68.48 67.34 TabG Laboratory Analytical Reports 3440 South 700 West ;alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801)263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-010 Client Sample ID: PIEZ-01_05202020 Collection Date: 5/20/2020 1240h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 2044h 5/29/2020 [358h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 67.7 £353.2 0.100 6.95 Report Date: 6/10/2020 Page 13 of 19 All analyses applicable lo lhe CWA, SOWA. and RCRA are perfom1ed in accordance to NELAC protocols Pertinent sampling information is localed on the al1ached COC Conliclenlinl Business Information: This repor1 is provided for the exclusi,e use of'1he ~dressee Pri, ile;es o~ su~eq~enl ~~ of lhe ~~e of this .co,~pany or an) 1~mber of its staff, or reproduc1io~ ~f this repo~ in ~on~ection .. ,,ith the il~\'ertise~ent, P~?moli°:'1 ~r ~ale of ~!Y .. ~rod~i or p~~ess, ~r in ~nn:<=!ion w!lh 1h~ n;-publication or lhis report 3440 South 700 West ,alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax:(801)263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-011 Client Sample ID: PIEZ-02_05202020 Collection Date: 5/20/2020 1225h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L ---- Contact: Tanner Holliday Date Method Reporting Analyzed Used Limit 6/5/2020 2101h E300.0 1.00 5/29/2020 1359h E353.2 0.100 Analytical Result Qual 14.4 0.679 Report Date: 6/10/2020 Page 14 of 19 All analyses applicable lo the CWA. SOWA, and RCRA are performed in accordance lo NELAC protocols Per1inent sampling information is located on the attached COC Conlidential Business Informalion: This report is proYided for 1he e_\'.clush-e tffe of the ~ddressee Pri, ile~es or sub_.seq~enl ~~e of the ~~1e of this .co":'pany or an) ~mber of its slaff, or reproductio.~ ~f this repo~ in .con~ection ... \\~lh 1he n~vertise~enl, P~?moli~ ~r sale of ?1!Y .. ~rod~cl or P~?Cess, ~r in ~nn~c!ion w(fh th~ r~-pubhat.HQJl of Lhis report American West ANAI.YTICAL 1.ABORATORIES 3440 South 700 West )alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (80 I) 263-8687 :-mail: awa1@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-012 Client Sample ID: PIEZ-03A_05202020 Collection Date: 5/20/2020 1305h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 2118h 5/29/2020 1400h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 88.3 E353.2 0.100 12.4 Report Date: 6/10/2020 Page 15 of 19 All analyses applicable to 1he CWA. SDW A. and RCRA are perfom1ed in accordance to NELAC prolocols Per1inent sampling inCormalion is localed on the altached COC ConfidenliDl Business lnfonruition: This repor1 is pr°'•ided ror 1he tsdusht me of lhe ~ddressee. Pri,·ile~es o,r su~seq~ent ~~e of lhe ~:u:ne of this .cm~pnny or any ,~mbet of its staff, or reproductio~ ~f lhis repo~ in ~on~eclion .. ,,,ith the D~\'ertisement, P~?moli~n ~r saJe of ~f ~rod~! or p~~S!i, ~r in ~nn~c!ion w~lh 1lt~ ~publicUJjon or Jhis repon 3440 South 700 West Mt Lake City, UT 84119 Phone: (801) 263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-004 Client Sample ID: TWN-01_05202020 Collection Date: 5/20/2020 950h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 1813h 5/29/2020 1338h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qua) E300.0 1.00 33.0 E353.2 0.100 2.24 Report Date: 6/10/2020 Page 7 of 19 All anal) ses applicable lo the CW A.. SOWA. and RCRA are performed in accordance to NELAC protocols. Pertinenl sampJint infornuuion is localed on the allached COC. Conlidentinl Bus.mess Information: This repon is provided for the ~'(('IU)i\·t use of 1he ~dressee Prfrile~es o~ sub~seq~enl ~~e of the ~~e or this .con:1p::111y or an) 1~7mbe1 of its staff, or repr,)duclio~ ~f this repo~ in .con!1cti10.~ "~th the ~~ertisement, P~?motio.n or sale of :1'!). t"'O<il~cl or p~~cess, ~r in ~nn:c~ion w!th lh~ r~-publiciJliott of ,his report INORGANIC ANALYTICAL REPORT 3440 South 700 West Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-006 Client Sample ID: TWN-02_05202020 Collection Date: 5/20/2020 1030h Received Date: Analytical Results Compound 5/27/2020 1215h Units Date Prepared ;aJt Lake City, UT 84119 Chloride mg/L mg/L Phone: (801)263-8686 foll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer Nitrate/Nitrite (as N) Date Analyzed 6/5/2020 1954h 5/29/2020 1340h Contact: Tanner Holliday Method Used E300.0 E353.2 Reporting Limit 1.00 0.500 Analytical Result 59.6 16.l Qual Report Date: 6/ I 0/2020 Page 9 of 19 All analyses applicable lo the CW A. SOWA. and RCRA are performed in accordance 10 NELAC protocols Pertinent samplini: information is localed on lhe allached COC Confidential Business Informal ion: This repon is provided for the exclusive use or1he ~c\dressee Pri, ile~es o! sub .. seq~enl ~~e of Lhe ~~e of this .con.1pany or M) 1~'!1ber of its stali, or reproducho~ ~f I his repo~ in ~01~1eclion ... ,,ilh the n~vertisemenL, P~?moli~ or sale of ~Y. -~nld~ct or p~~ess, ~r in ~onn~~ion w~lh lh~ r~-pubf1co1iQn of'lhis report 3440 South 700 West ;aJt Lake City, UT 84119 Phone: (801)263-8686 foll Free: (888) 263-8686 Fax: (80 I) 263-8687 ~-mail: awal@awal-Jabs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-007 Client Sample ID: TWN-03 _ 05212020 Collection Date: 5/21/2020 103 5h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 2011 h 5/29/2020 1342h ---- Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 2.00 136 E353.2 0.200 24.0 Report Date: 6/10/2020 Page 10 of 19 All analyses applicable to the CW A. SOWA. and RCRA are performed in accordance to NELAC protocols Pertinent sampling information is localed on lhe au ached COC Confidential Business Information: This repon is prO\•ided rortlk! exclusiYe use of the ~ddressee Pri, ile~es o.f sub~seq~ent ~~e of lhe ~:u:"e of this .con;1p:iny or M) 1~mber of its slaIT: or reproduc1io~ ~f this repo~ in ~on?eclion~ \\·ith the ~\'ertisemeot, P~?moli~ or saJe of~!~. ~rodl~l or p~~U, ~r in ~nn~cJion w!th lh~ r!·P':'blicalio1l of I his report INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-003 Client Sample ID: TWN-04 _ 05202020 ANALn,cAL LAB0R.&.T0A11 s Collection Date: 5/20/2020 914h 3440 South 700 West )alt Lake City, UT 84 I 19 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (80 I) 263-8687 ~-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Contact: Tanner HoJliday Date Method Reporting Analytical Analyzed Used Limit Result Qua) 6/5/2020 1723h E300.0 1.00 25.1 5/29/2020 1337h E353.2 0.100 1.75 ---- Report Date: 6/10/2020 Page 6 of 19 All analyses applicable lo the CW A. SOWA. and RCRA are performed in accordance to NELAC protocols Per1inenc sampling information is localed on the allached COC Conlidenliol Business lnfonnation: This repon is pr0l1ided for the esclusi,·e use of lhe ~dressee. Pri,·ile~es o_f sub~seq~enl ~~e of the ~~e of I his .con:ipany or any ~';lber of ils staff, or reproductio~ ~~ this repo~ in ~o~iection~ with the a~~'er1ise~ent, fl~?moli~ ~r ~aJe of ?1!): ~rod~ct or P~?cess, ~r in ~nn~c~ion w~lh lh~ r~-p~blication of this report 3440 South 700 West ,alt Lake City, UT 84119 Phone: (801)263-8686 foll Free: (888) 263-8686 Fax: (801)263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-005 Client Sample ID: TWN-07 _ 05212020 Collection Date: 5/21/2020 1015h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 1937h 5/29/2020 1339h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 126 E353.2 0.100 14.6 Report Date: 6/10/2020 Page 8 of 19 All analyses applicable lo 1he CWA. SDWA. and RCRA are IJerformed in accordance to NELAC protocols Per1inenl SDmpling information is localed on Lhe attached COC Confidential Business lnfonnalion: This repon is prm•ided for 1he C.'\:Cl~\t use of the ~ddressee Pri, ile~es or sub~seq~1enl ~~e of the ~~1e of this,con_ipany or M) ,~mbe, of ils slaff, or reproduclio~ ~f this repo~ in ~0~1ec1ion~ ,vith lhe ~,·er1ise~en1, P~?rnotio.n 01 ~aJe of ~!Y. -~roct~ct or P~?cess, ~r in ':°nn:c!ion \\'!lh lh~ r~-publlcnlion of 1his report 3440 South 700 West ,alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax:(801)263-8687 :-mail: awal@awal-labs.com web: www.awal-Iabs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-002 Client Sample ID: TWN-18_05202020 Collection Date: 5/20/2020 836h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 1706h 5/29/2020 1323h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 47.4 E353.2 0.100 0.236 Report Date: 6/10/2020 Page 5 of 19 All anal) ses applicable lo lhe CWA, SOWA. and RCRA are perfomted in accordance 10 NELAC protocols Pertinenl snmpling information is located on 1.he attached COC. Confidenlial Business lnronnation: This repon is pro\'ided for 1he exclusive use or the ~ddressee Pri\·ile~es orsub .. seq~enl ~~e of1he ~~1e of this .con:ipany or an) ~mber of ilS staff, or reproduclio~ ~f this repo~ in ~on~echon .. \\ith lhe a<!''ertisement, P~?moti~ ~r ~ale of ?-1!.Y. .~rodt~t or p~~cess, ~r in ~onn~c(ion "'!'h th~ r!·publication of this reporl American West ANALYTICAL I.ABORATOA1£S 3440 South 700 West ,alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801)263-8687 !-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-001 Client Sample ID: TWN-l 8R _ 05202020 Collection Date: 5/20/2020 814h Received Date: 5/27/2020 1215h Analytical Results Compound Chloride Nitrate/Nitrite (as N) Date Units Prepared mg/L mg/L Date Analyzed 6/5/2020 1650h 5/29/2020 1320h ----------------- Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 < 1.00 E353.2 0.100 < 0.100 Report Date: 6/10/2020 Page 4 of 19 All analyses applicable to the CWA. SOWA. Wld RCRA are performed in accordance to NELAC protocols Per1ineru sampling informalion is located on lhe al1oched COC, Confidenlial Busine.ss Information; This report is pro\'ided for the exclusire use of1he ~ddressee Prfrile~es oF sub .. seq~ent ~1:e of the ~:u:'1e of lhi~ .co1~pany or any ~~ber of ils slaff, or reproductio~ ~~ this rep~~ in ~~1ection .. \\ith the a~~·ertise~ent, P~?motio.n o_r ~ale of ?-1!)~ ~rod~cl or p~~ces.s, ~r in ~onm;c!io11 w!lh 1h~ r~-publication of this repon INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Chloroform 2020 Lab Sample ID: 2005695-013 Client Sample ID: TW4-22_05272020 ANALvr,cAL LADORAroR1Es Collection Date: 5/27/2020 935h 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801)263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer Received Date: 5/29/2020 I 050h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/9/2020 1956h 6/1/2020 1434h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 5.00 578 E353.2 0.500 60.5 ------- Report Date: 6/12/2020 Page 18 of 48 All anal~ ses applicable 10 the CWA, SDWA. and RCRA are perfom1ed in accordance to NELAC pf tocolJ.. Pt1hn~n1 sampliny informn11oe1 is located on lhe nunched COC. (.'oolidcntiol Business lnl'ornui11on: This repon is pro,·ided for lhe e:xclusire use of the ~ddressee Pri,·ile~es o_f sub,_seq~ent ~1;e of lhe ~~e of this .co1~1pony or nny ~mber of its slnIT, or rtprodoct,~! ~flhis repo~ in .con!1«1io1~ wHh the u~~·enise~ent, P~?moli<>!l ~~e of~!~'. ~rodl)CI tit ftl' .. ocess, ~r in :°nn:c!ion w/th th~ r;_·p~blicniion of this report 3440 South 700 West ~alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Chloroform 2020 Lab Sample ID: 2005695-002 Client Sample ID: TW4-24_05272020 Collection Date: 5/27/2020 925h Received Date: 5/29/2020 1050h Analytical Results Date Compound Units Prepared Chloride Nitrate/Nitrite (as N) mg/L mg/L ---------------- Date Analyzed 6/9/2020 1512h 6/1/2020 1416h --- Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual £300.0 10.0 1,060 E353.2 0.500 41.7 ---- Report Date: 6/12/2020 Page 7 of 48 All anal, ses applicable to lhe CW A. SOWA. and RCRA aie perfom1ed in accordance to NELAC protocols Pertinenl sampling information is located on the auached COC Conridential Busin~s Jnformation: This report is provided for 1he c.~dUSI\C us.c of the ~ddressee Pri, ile~es o_f sub__seq~ent ~~e of the ~~e of this .con;ipany or any ~mber of its staIT, or repr1lducti~ ~f this repo~ in ~®!1ec1ion~ with the n~vertise1'!1ent, P~?molio.n ~r ~ale of ?-1!~· .. ~rodl'.Ct or p•:?Cess, ~r in ~onn~c!ion w!th th~ r~-p~blica.tion or this report 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801)263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-Iabs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Chloroform 2020 Lab Sample ID: 2005695-001 Client Sample ID: TW4-25_05272020 Collection Date: 5/27/2020 915h Received Date: 5/29/2020 1050h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/9/2020 1455h 6/1/2020 1413h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 2.00 76.8 E353.2 0.100 0.851 -------------- Report Date: 6/12/2020 Page 6 of 48 All arn11) ses applicable to lhe CW A. SOWA, and RCRA are performed in accordance to NELAC prolocols Pertinent sampling informnlion is located on the aUached COC Conridenlinl Business [nformalion: This report is provided for 1he exclush e use of the ~rldressee Pridle~es of su~seq~enl ~~e of the ~~e or lhis .co1~pany or nny ~7mber of its slaff, or reproduclio1~ ~fthis repo~ in ~o~ectionp \\·ith the n~:ertisement. p~~molio.n ~r ~aJe of ~!Y. ~rod~cl or p1:?Cess, ~r in 70M~c~ion w~th th~ r:-publication of lhis report American West ANALYTICAL LAB0RATOR1f6 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801) 263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-009 Client Sample ID: TWN-60_05202020 Collection Date: 5/20/2020 1330h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 2134h 5/29/2020 1344h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 < 1.00 E353.2 0.100 < 0.100 Report Date: 6/ I 0/2020 Page 12 of 19 All analyses applicable to the CWA_ SDW A. and RCRA are performed in accordance to NELAC protocols Pertinent sampling information is located on the allached COC Confiden1ial Business lnrorm::ilion: This repon is pro\'ided for the i:sol~\'t i.tR.of the ~dressee-Pri,·ile~es or su~seq~ent ~e of the ~~1e of !his .co1~pany or any ~mber of ils slafr,. or repmducli~ ~f this repo~ in ~~1ection ... \\ith the ™!~enise~lenl, P~?motio.n ~r ~aJe of ~!Y. -~rod~l or p1:~ss, ~r in ~onn:c.lion ,,·!lh lh~ r1;-publk::uio1\ of lllis report 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801)263-8686 foll Free: (888) 263-8686 Fax:(801)263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Chlorofonn 2020 Lab Sample ID: 2005695-017 Client Sample ID: TW4-60_05272020 Collection Date: 5/27/2020 13 lOh Received Date: 5/29/2020 1050h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/9/2020 2301h 6/1/2020 1444h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 < 1.00 E353.2 0.100 <0.100 Report Date: 6/12/2020 Page 22 of 48 All anolyscs aprlicnblc to the CWA. SDWA, and RCRA arc pcrfom1cd in accord:rncc to NELAC protocols. Pcrtincnl sampling infonnation is located on the attached COC. Confidential Business Infom1ation: This report is provided for the ('Xt•lu"1\i.· 11sc or the addressee, Privilc~cs o~ sub_scq~cnt use of the ·~i:nc of this company or any ~1?1bcr or its staff, or rcproductio~ ~~ this repo~ in ~on~cction_ with the a~~crtisc~cnt, p~omolio_n ~r ~ale of ?~Y. ~rod~ct or P~?ccss, ~r in ~onn~ction v.:ith the n~-pubH~11100 of this report American West ANALYTICAL LABORATORIES 3440 South 700 West ;alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801)263-8687 :-mail: awal@awal-Jabs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer INORGANIC ANALYTICAL REPORT Client: Energy Fuels Resources, Inc. Project: 2nd Quarter Nitrate 2020 Lab Sample ID: 2005623-008 Client Sample ID: TWN-65 _ 05202020 Collection Date: 5/20/2020 914h Received Date: 5/27/2020 1215h Analytical Results Date Compound Units Prepared Chloride mg/L Nitrate/Nitrite (as N) mg/L Date Analyzed 6/5/2020 2027h 5/29/2020 1343h Contact: Tanner Holliday Method Reporting Analytical Used Limit Result Qual E300.0 1.00 25.4 E353.2 0.100 1.71 Report Date: 6/ I 0/2020 Page 11 of 19 All analyses applicable lo lhe CW A. SDW A, and RCRA are perfomled in accordance lo NELAC protocols Pertinenl sampling information is localed on the allached COC Confidential Business lnformolion: This repon is prm•ided for the exclusi\·e use of the ~ddressee Pri, ile~es o.r su~seq~enl ~~e of lhe ~~ne of lhis .co":'pan)' or anr ~i:"ber o(its slatr or reproduclio~ ~f this repo~ in ~on?eclion~ with the a~,,ertisemenl, p~moli~n or sale of ~~y ~rod~cl or P~?cess, ~r in ?>nn:c!ion w!lh th~ i:-p~blicaJion of lhis report Tanner Holliday Energy Fuels Resources, Inc. 6425 South Hwy 191 American West Blanding, UT 84511 ANALVTICAl LAOORATORIES 3440 South 700 West falt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 !-mail: awa1@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer TEL: (435) 678-2221 RE: 2nd Quarter Nitrate 2020 Dear Tanner Holliday: Lab Set ID: 2005623 American West Analytical Laboratories received sample(s) on 5/27/2020 for the analyses presented in the following report. American West Analytical Laboratories (AW AL) is accredited by The National Environmental Laboratory Accreditation Program (NELAP) in Utah and Texas; and is state accredited in Colorado, Idaho, New Mexico, Wyoming, and Missouri. All analyses were performed in accordance to the NELAP protocols unless noted otherwise. Accreditation scope documents are available upon request. If you have any questions or concerns regarding this report please feel free to call. The abbreviation "Surr" found in organic reports indicates a surrogate compound that is intentionally added by the laboratory to determine sample injection, extraction, and/or purging efficiency. The "Reporting Limit'' found on the report is equivalent to the practical quantitation limit (PQL). This is the minimum concentration that can be reported by the method referenced and the sample matrix. The reporting limit must not be confused with any regulatory limit. Analytical results are reported to three significant figures for quality control and calculation purposes. Thank You, J G Digitally signed 0$9 . by Jose G. Rocha Rocha Date: 2020.06.10 14:48:00 -06'00' Approved by: .__ ___________ _. Laboratory Director or designee Report Date: 6/ I 0/2020 Page I of 19 All anaJ~ ses applicable to the CW A. SOW A. and RCRA are perfom1ed in accordance to NELAC pro,ocQls. Pcr1inmt sampling informa1ion is localed on the attached COC. CQnf1dt;1111al Business Jnfonnation: This repon is pro,•ided for the C'\.Chtiho USO or1he ~dressee Pri,·ile~es o~ sub .. seq~ent ~~e of 1he ~~,e or this .cm~pany or ru1y ~mber of its staff, orr~ptoduct qi~ ~r1his repo~ in .con~eclion" "·i01 the n<!~·crtise~t, P~?mo1i~1 ~ ~I\IO: of~!): .~rod~cl or P~?Cess, ~r in <;0nn:c~ion w!th th~ r~-pubHauioo or this report SAMPLE SUMMARY American West Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday ANAI.YTICAL LABOAATORlr:s Project: 2nd Quarter Nitrate 2020 Lab Set ID: 2005623 Date Received: 5/27/2020 1215h Lab Sample ID Client Sample ID Date Collected Matrix Analysis 3440 South 700 West 2005623-00 IA TWN-l 8R 05202020 5/20/2020 814h Aqueous Anions, E300.0 ;alt Lake City, UT 84119 2005623-001B TWN-18R 05202020 5/20/2020 814h Aqueous Nitrite/Nitrate (as N), E353.2 2005623-002A TWN-18_05202020 5/20/2020 836h Aqueous Anions, E300.0 2005623-002B TWN-18 05202020 5/20/2020 836h Aqueous Nitrite/Nitrate (as N), E353.2 Phone:(801)263-8686 2005623-003A TWN-04 05202020 5/20/2020 914h Aqueous Anions, E300.0 Toll Free: (888) 263-8686 2005623-003B TWN-04_05202020 5/20/2020 914h Aqueous Nitrite/Nitrate (as N), E353.2 Fax: (80 I) 263-8687 2005623-004A TWN-01 05202020 5/20/2020 950h Aqueous Anions, E300.0 2005623-004B TWN-01 05202020 5/20/2020 950h Aqueous Nitrite/Nitrate (as N), E353.2 :-mail: awal@awal-labs.com 2005623-005A TWN-07 05212020 5/21/2020 1015h Aqueous Anions, E300.0 2005623-005B TWN-07_05212020 5/21/2020 1015h Aqueous Nitrite/Nitrate (as N), E353.2 web: www.awal-labs.com 2005623-006A TWN-02 05202020 5/20/2020 1030h Aqueous Anions, E300.0 2005623-006B TWN-02 05202020 5/20/2020 1030h Aqueous Nitrite/Nitrate (as N), E353.2 2005623-007 A TWN-03 05212020 5/21/2020 1035h Aqueous Anions, E300.0 Kyle F. Gross 2005623-007B TWN-03 05212020 5/21/2020 1035h Aqueous Nitrite/Nitrate (as N), E353.2 Laboratory Director 2005623-00SA TWN-65 05202020 5/20/2020 914h Aqueous Anions, E300.0 2005623-00SB TWN-65 05202020 5/20/2020 914h Aqueous Nitrite/Nitrate (as N), E353.2 Jose Rocha 2005623-009A TWN-60 05202020 5/20/2020 1330h Aqueous Anions, E300.0 QA Officer 2005623-009B TWN-60 05202020 5/20/2020 1330h Aqueous Nitrite/Nitrate (as N), E353.2 2005623-01 OA PIEZ-01 05202020 5/20/2020 1240h Aqueous Anions, E300.0 2005623-0 l OB PIEZ-01_05202020 5/20/2020 1240h Aqueous Nitrite/Nitrate (as N), E353.2 2005623-01 IA PIEZ-02 05202020 5/20/2020 1225h Aqueous Anions, E300.0 2005623-01 IB PIEZ-02 05202020 5/20/2020 1225h Aqueous Nitrite/Nitrate (as N), E353.2 2005623-012A PIEZ-03A 05202020 5/20/2020 1305h Aqueous Anions, E300.0 2005623-012B PIEZ-03A 05202020 5/20/2020 1305h Aqueous Nitrite/Nitrate (as N), E353.2 Report Date: 6/10/2020 Page 2 of 19 All analyses applic.ible to lhe CWA. SDWA. and RCRA are performed in accordance to NELAC protocols Pertinenl sampling informotion is located on lhe all ached COC Confiden1ial Business lnformation: This report is provided for the e."(chisi\·C' use oft he ~ddressee Privile~es o.r sub .. seq~enl ~1?e of the ~?1:"e of lhis .co1~pany or M) 1~mber of its s1aff, or reproduclio~ ~f 1his repo~ in ~0~1ection ... \\ith the a~vertisement, P~?moti~ ~r sale of :11~Y. ~rodl~t or p~~s, ~r in ~nn~c!ion w!lh th~ r~·publiW!ion or1his report 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801)263-8686 foll Free: (888) 263-8686 Fax:(801)263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer Inorganic Case Narrative Client: Contact: Energy Fuels Resources, Inc. Tanner Holliday Project: Lab Set ID: Sample Receipt Information: Date of Receipt: Date(s) of Collection: Sample Condition: C-0-C Discrepancies: 2nd Quarter Nitrate 2020 2005623 5/27/2020 5/20-5/21/2020 Intact None Holding Time and Preservation Requirements: The analysis and preparation of all samples were performed within the method holding times. All samples were properly preserved. Preparation and Analysis Requirements: The samples were analyzed following the methods stated on the analytical reports. Analytical QC Requirements: All instrument calibration and calibration check requirements were met. All internal standard recoveries met method criterion. Batch QC Requirements: MB, LCS, MS, MSD, RPD: Method Blanks (MB): No target analytes were detected above reporting limits, indicating that the procedure was free from contamination. Laboratory Control Samples (LCS): All LCS recoveries were within control limits, indicating that the preparation and analysis were in control. Matrix Spike / Matrix Spike Duplicates (MS/MSD): All percent recoveries and RPDs (Relative Percent Differences) were inside established limits, indicating no apparent matrix interferences. Duplicate (DUP): The parameters that required a duplicate analysis had RPDs within the control limits. Corrective Action: None required. Report Date: 6/10/2020 Page 3 of 19 All analyses applicable to 1he CWA SOW A. and RCRA are perfom1ed in accordance to NE LAC protocols. Pertinent sampling information is localed on the attached COC Confidential Business lnfonnation: This report is pro\'ided for the exclusiYe use of the ~ddressee Pri, ile~es of su~seq~ent ~,~e of the ~:t',"e of lhis .co1~pany or an)' ,~mber of its slaff, or reproductio~ ~f this repo~ in .co~eclio~ ,dth the a~,·ertise~ent, P:?motio.n or saJe of ?'!~~-~rodl~CI or p~~, ~r in ~nni;c!ion \\'!lh th~ r:-publicalion of this report American West ANALYTICAL LABORATORIES 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, Toll Free: (888) 263-8686. Fax: (801) 263-8687 e-mail : awal@awal-labs.com, web: www.awal-labs.com C SUMMARY REPORT Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday WC Lab Set ID: 2005623 Project: 2nd Quarter Nitrate 2020 Analyte Result Units Method Lab Sample ID: LCS-R139602 Date Analyzed: 06/05/2020 1633h Test Code: 300.0-W Chloride 5.06 mg/L E300 0 Lab Sample ID: LCS-R139282 Date Analyzed: 05/29/2020 1302h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.06 mg/L E353.2 Lab Sample ID: LCS-R139283 Date Analyzed: 05/29/2020 1336h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.07 mg/L E353.2 MDL 0.0565 0.00494 0.00494 Reporting Limit 0.100 0.0100 0.0100 Dept: QC Type: LCS Amount Spiked Spike Ref. Amount %REC 5.000 0 101 l.000 0 106 1.000 0 107 Limits 90 -110 90 -110 90 -110 Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPO Ref. RPO Limit Amt %RPO Qua) Report Date: 6/10/2020 Page 16 of 19 analyses applicable to the CWA. SOWA, and RCRA are perfom,ed in accordance to NELAC protocols Pertinent sampling information is located on the attached COC ConfidentiaJ Business lnfonnation: This report is provided for the exclusive use of the addressee Privileges of subsequent use of ti- ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process. or in connection with there-publication of this report for any purpose other than for the addressee will be granted only on contact This ANALYTICAL LABORATORIES Client: Energy Fuels Resources, Inc. Lab Set ID: 2005623 Project: 2nd Quarter Nitrate 2020 Analyte Result Lab Sample ID: MB-RI39602 Date Analyzed: Test Code: 300.0-W Chloride < 0.100 Lab Sample ID: MB-RI39282 Date Analyzed: Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) < 0.0100 Lab Sample ID: MB-RI39283 Date Analyzed: Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) < 0.0100 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, Toll Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com C SUMMARY REPORT Contact: Dept: QC Type: Reporting Amount Spiked Units Method MDL Limit 06/05/2020 1616h mg/L E300.0 0.0565 0.100 05/29/2020 1301h mg/L E353 2 0.00494 0.0100 05/29/2020 1334h mg/L E353.2 0.00494 0.0100 Tanner Holliday WC MBLK Spike Ref. Amount %REC Limits Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPO Ref. RPO Amt %RPO Limit Qual Report Date: 6/10/2020 Page 17 of 19 analyses applicable to the CWA, SDWA, and RCRA are performed in accordance to NELAC protocols Pertinent sampling information is located on the attached COC, Confidential Business Infom,ation: This report is provided for the exclusive use of the addressee_ Privileges of subsequent use oft~ ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee will be granted only on contact This ANALYTICAL LABORATORIES Client: Energy Fuels Resources, Inc. Lab Set ID: 2005623 Project: 2nd Quarter Nitrate 2020 Analyte Result Lab Sample ID: 2005623-00JAMS Date Analyzed: Test Code: 300.0-W Chloride 74.7 Lab Sample ID: 2005623-004AMS Date Analyzed: Test Code: 300.0-W Chloride 82.0 Lab Sample ID: 2005623-001 BMS Date Analyzed: Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.03 Lab Sample ID: 2005623-009BMS Date Analyzed: Test Code: N02/N03-W-353.2 --- Nitrate/Nitrite (as N) 0.997 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686. Toll Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com C SUMMARY REPORT Contact: Dept: QC Type: Reporting Amount Spiked Units Method MDL Limit 06/05/2020 1740h --- mg/L E300.0 0.565 1.00 50.00 06/05/2020 1830h mg/L E300,0 0.565 1.00 50.00 05/29/2020 1321 h - mg/L E353.2 0.00494 0.0100 1.000 05/29/2020 1345h mg/L E353.2 0.00494 0.0100 1.000 Tanner Holliday WC MS Spike Ref. Amount %REC 25.1 99.4 33 98.1 0.00801 102 0 99.7 Limits 90-110 90 -110 90 -110 90 -110 Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPO Ref. RPO Amt %RPO Limit Qual Report Date: 6/10/2020 Page 18 of 19 analyses applicable to the CWA. SOWA, and RCRA are performed in accordance to NELAC protocols Pertinent sampling informat10n is located on the attached COC Confidential Business Information: This report is provided for the exclusive use of Lhe addressee Privileges of subsequent use of tl- ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee will be grantC"d only on contact-This 3440 South 700 West Salt Lake City, UT 84119 Kyle F. Gross Phone: (801) 263-8686, Toll Free: (888) 263-8686. Fax: (801) 263-8687 Laboratory Director e-mail: awal@awal-labs.com, web: www.awal-labs.com Jose Rocha QA Officer ANALYTICAL LABORATORIES ~ C SUMMARY REPORT Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday Lab Set ID: 2005623 Dept: WC Project: 2nd Quarter Nitrate 2020 QC Type: MSD Reporting Amount Spiked Spike Ref. RPO Ref. RPO Analyte Result Units Method MDL Limit Amount %REC Limits Amt %RPO Limit Qual Lab Sample ID: 2005623-00JAMSD Date Analyzed: 06/05/2020 1757h Test Code: 300.0-W Chloride 75.2 mg/L E300.0 0.565 1.00 50.00 25.1 100 90 -110 74.7 0.574 20 Lab Sample ID: 2005623-004AMSD Date Analyzed: 06/05/2020 1847h Test Code: 300.0-W --- Chloride 81.9 mg/L E300 0 0.565 1.00 50.00 33 97.8 90 -110 82 0.197 20 Lab Sample ID: 2005623-00 lBMSD Date Analyzed: 05/29/2020 1322h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.04 mg/L E353.2 0.00494 0.0100 1.000 0.00801 103 90 -110 1.03 0.971 JO Lab Sample ID: 2005623-009BMSD Date Analyzed: 05/29/2020 1357h Test Code: N02/N03-W-353.2 -- Nitrate/Nitrite (as N) 1.05 mg/L E353.2 0.00494 0.0100 1.000 0 105 90 -110 0.997 5.53 10 Report Date: 6/10/2020 Page 19 of 19 analyses applicable to the CWA, SOWA, and RCRA arc perfonned in accordance to NELAC protocols Pertinent sarnphng infonnation is located on the attached COC Confidential Business lnfom,ation: This report is provided for the exclusive use of the addressee Privileges of subsequent use of ti- ne of this company or any member of its staff, or reproduction of thls report in connection with the advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee will be granted only on contact. This American West Analytical Laboratories Rpt Emailed: UL Denison WORK ORDER Summary Work Order: 2005623 Page 1 of2 Client: Energy Fuels Resources, Inc. Due Date: 6/10/2020 Client ID: ENE300 Contact: Tanner Holliday Project: 2nd Quarter Nitrate 2020 QC Level: III WO Type: Project Comments: QC 3 (no chromatograms). EDD-Denison. CC KWeinel@energyfuels.com; ~ Sample ID Client Sample ID Collected Date Received Date Test Code Matrix Sel Storage 2005623-00lA TWN-18R_05202020 5/20/2020 0814h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-00IB N02/N03-W-353.2 df-no2/no3 1 SEL Analytes: N03N02N 2005623-002A TWN-18_05202020 5/20/2020 0836h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-002B N02/N03-W-353.2 df-no2/no3 1 SEL Analyzes: N03N02N 2005623-003A TWN-04 _ 05202020 5/20/2020 0914h 5/27/2020 1215h 300.0-W Aqueous df. cl I SEL Analytes: CL 2005623-003B N02/N03-W-353.2 df. no2/no3 1 SEL Analytes: N03N02N 2005623-004A TWN-Ol_ 05202020 5/20/2020 0950h 5/27/2020 1215h 300.0-W Aqueous df-cl I SELAnalytes: CL 2005623-004B N02/N03-W-353.2 df. no2/no3 1 SEL Analyzes: N03N02N 2005623-005A TWN-07 _ 05212020 5/21/2020 1015h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-00SB N02/N03-W-353.2 df. no2/no3 I SEL Ahalytes: N03N02N 2005623-006A TWN--02 _ 05202020 5/20/2020 1030h 5/27/2020 1215h 300.0-W Aqueous elf. cl I SEL Analytes: CL 2005623-006B N02/N03-W-353.2 df. no2/no3 I SEL Analytes: N03N02N 2005623-007 A TWN-03_05212020 5/21/2020 1035h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-007B N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N Printed: 05/28/20 12:14 LABORATORYCHECK: %M 0 RTO CNO TAT 0 QCO LUOO HOK __ HOK __ HOK __ COC Emailed WORK ORDER Summary Work Order: 2005623 Page2 of2 Client: Energy Fuels Resources, Inc. Due Date: 6/10/2020 Sample ID Client Sample ID Collected Date Received Date Test Code Matrix Sel Storage 2005623-00BA TWN-65_05202020 5/20/2020 0914h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-00SB N02/N03-W-353.2 df-no2/no3 1 SEL Analytes: N03N02N 2005623-009A TWN-60_05202020 5/20/2020 1330h 5/27/2020 1215h 300.0-W Aqueous elf-cl 1 SEL Analytes: CL 2005623-0098 N02/N03-W-353.2 elf-no2/no3 I SEL Analytes: N03N02N 2005623-01 OA PIEZ-01_05202020 5/20/2020 1240h 5/27/2020 1215h 300.0-W Aqueous df-cl 1 SEL Analytes: CL 2005623-0108 N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 2005623-0llA .PIEZ-02_05202020 5/20/2020 1225h 5/27/2020 1215h 300.0-W Aqueous df-cl I SEL Analytes: CL 2005623-01 lB N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 2005623-0l2A ·· ·PIEZ-03A _:os202020 ?/20/7020 1305h 5/27/2020_1215)1 300.0-W Aqueous df-cl ... -... . .......... 1 SEL Analytes: CL 2005623-012B N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N . . .. -· ...... -..... , .. ,..,, .... • .... _..._ >-·• ,.._ ··-: .. ~ ... . ,.,, , ........ . ··""-,......... .,--· .... ,,,_ ........... ~_,,.,, ___ ...,..,. ........ ~-..... ,. . ,--:-....... . ........ .,.,_ .. _......,,_s. ... --·<---'"·-... ····· -....... Printed: 05/28/20 12:14 LABORATORY CHECK: %M O RT O CN O TAT O QC O LUO 0 HOK ___ HOK __ _ HOK___ COC Emailed~---- 2 ! e American West Analytical Laboratories 463 W. 3600 S. Salt Lake City, UT 84115 Phone# (801 J 263-8686 Toll Free # (888) 263~686 .t~ Fax# (801) 263-8687 Email awal@awaHabs.com www.awal-labs.com Client: Energy Fuels Resources, Inc. Address: 6425 S. Hwy. 191 Blanding, UT 84511 Contact: Tanner Holliday Phone#: (4351678-2221 Cell#: gpaJmeI@eaeri,lii.els.com; KWeliiei@enerr:,faels.com; Email: thoDiclawi)enersz:!!!els.com Project Name: 2nd Quarter Nitrate 2020 Project#: PO#: Sampler Name: Tanner Holliday Date Samole ID: Sampled TWR-18R_05202020 5/20/2020 TWJl-18_05202020 5/20/2020 TWJl-04_05202020 5/20/2020 TWll'-01_05202020 5/20/2020 'l'Wl'l-07_06212020 5/21/2020 TWN-02_06202020 5/20/2020 TWN-03_06212020 5/21/2020 1 TWN-65_05202020 5/20/2020 1 TWN-60 05202020 5/20/2020 l PIEZ-01_05202020 5/20/2020 1 PIEZ-02_05202020 5/20/2020 ! PIEZ.03A_05202020 5/20/2020 ! Rollnqui,,t,nd by: -'\ 1J // / / ate: run~a ~--~· _ 5126/202( Time: ....... _, T_.Hollldov 110( Rellnqulshed by: Date: l~lnnoh,~ Time: IPnntName: Relloqulshod by: Date: Sianot,.o ~Imo: IPnntName: Ftollnqulnd by: Dete; l'""""'uro Time: Prlnl Name: Time Sampled 814 836 914 950 1015 1030 1035 914 1330 1240 1225 1305 Received by: Sianature PrtnlNeme: [Received by: lsianature Print Name: Received by: Sian.at:ure Prini.Name: I CHAIN OF CUSTODY All analysis will be conducted using NELAP accredited methods end all data will be reported using AW/IJ.'s standa,d analyle lists and reporting limits (PQLj unleso specifically requested otherwise on this Chain of Custody end/or attached docum<mlatlon. QC Level: I Tum Around Time: UrJess other arrangements have been made, signed reports will be emailed by 5:00 pm on 3 Standard the day they are due. X Include EDD: LOCUS UPLOAD EXCEL Field Filtered For. For Compliance With: 0 NELAP 0 RCRA 0 CWA 0 SOWA D ELAP/A2LA c' 0 NLLAP ~ 0 D Non-Compliance e3 c:, 0 Other. 0) I!! ~ ... " ~ C'l 0 C: c:, ~ "' i ~ c:, Known Hazards 0 ! IJ) (.) ..... ~ & t'l '5 E i 'O "' Samole Comments .. V, 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X 2 w X X Date: Special Instructions: Time: Date: tnme: Date: Time: --Received by: / LJ 11t ,-i\ ~t JA) Oate: ~l, 2-f l.P Sianature , ""' -~> --:!"'~ l J.. u.Y-, Time: I Li: IC:-Print Name: ·- mostaz3 AWAI. Lab Sample Set# Page 1 of 1 Due Da~l U} { Z1:) Laboratory Use Only S&mlNOW-. llf5 , ~ hand-- 2 Ambient~ Temperature tJ1 7 ·c 3 4 Received Broken/Leaking y N (lffll)<OpOfly 8'e) 5 ~rty PJose,vod y N ed n!-y N 6 ReceiVed Within y 't)"ttflt//JTimes N COCTapaWas 1 PnJSent on Outer P~ y N . 2 Unbroken on Outer y N NA 3 Present on Sample y N NA 4 Unbroken on Sample y N NA ~ M8=f) Laheb end COC · y N Analysis Ammonia COD Cvanide Metals N02/N03 O&G Phenols Sulfide TKN TP04 CrVI+ Procedure: Frequency: Preservation Check Sheet s amo le Set Ext Preservative ...-rot --002 -~ ~ ...-oos-~ pH<2H2S04 nH<2H2S04 oH>12NaOH oH<2HN03 nH<2H2S04 1, { />_f:.:. \Jeh '-v.es \ll'h '1~ 1-ve-c. oH<2HCL 1 • ,, J I "' pH<2H2S04 pH>9NaOH, Zn Acetate oH<2H2S04 nH<2H2S04 pH>9 (Nffi)2S04 Pour a small amount of sample in the sample lid Pour sample from lid gently over wide range pH paper Do Not djp the pH paper in the sample bottle or lid rOCf7 'rvP5S I doH -COi -tt,<'j \_JP~ '1e.,s I I -01-0 -on 1ves IV~ I f I) 2) 3) 4) 5) 6) 7) If sample is not preserved, properly list its extension and receiving pH in the appropriate colwnn above Flag COC, notify client ifrequested Place client conversation on COC Samples may be adjusted All samples requiring preservation * + ~ # • The sample required additional preservative upon receipt. The sample was received unpreserved. The sample was received unpreserved and therefore preserved upon receipt. The sample pH was unadjustable to a pH < 2 due to the sample matrix. The sample pH was unadjustable to a pH > __ due to the sample matrix interference . -01'2..... Ives , Lab Set ID: pH Lot#: 2PDS:Co'2..3 loZ-99 Tanner Holliday Energy Fuels Resources, Inc. 6425 South Hwy 191 American West Blanding, UT 84511 ANIILYTICAL LABORATORIES 3440 South 700 West ;alt Lake City, UT 84119 Phone: (801)263-8686 Toll Free: (888) 263-8686 Fax: (80 I) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer TEL: (435) 678-2221 RE: 2nd Quarter Chloroform 2020 Dear Tanner Holliday: Lab Set ID: 2005695 American West Analytical Laboratories received sample(s) on 5/29/2020 for the analyses presented in the following report. American West Analytical Laboratories (AWAL) is accredited by The National Environmental Laboratory Accreditation Program (NELAP) in Utah and Texas; and is state accredited in Colorado, Idaho, New Mexico, Wyoming, and Missouri. All analyses were performed in accordance to the NELAP protocols unless noted otherwise. Accreditation scope documents are available upon request. If you have any questions or concerns regarding this report please feel free to call. The abbreviation "Surr" found in organic reports indicates a surrogate compound that is intentionally added by the laboratory to determine sample injection, extraction, and/or purging efficiency. The "Reporting Limit" found on the report is equivalent to the practical quantitation limit (PQL). This is the minimum concentration that can be reported by the method referenced and the sample matrix. The reporting limit must not be confused with any regulatory limit. Analytical results are reported to three significant figures for quality control and calculation purposes. Thank You, Approved by: K I F Digitally signed y e . by Kyle F. Gross Date: Gross 2020.06.12 12:29:22 -06'00' ~------------~ Laboratory Director or designee Report Date: 6/12/2020 Page 1 of 48 All anal)ses applicable to lhe CWA. SDWA. and RCRA rue perfom1ed in accordance to NELAC prolocols Pertinenl sampling informalion is located on the attached COC Confidential Business tnrormation: This report is prO\•ided rot dn: e.."<clu i,·e usc of the ~ddressee Pri,·ile~es o,r su~seq~enl ~~e of lhe ~~le of lhis .con:1pany or :ut) ~~mbe1 of its staff, or reproducliot~ ~f this repo~ in ~on!1ecl1on~ ,,-i1h Jhe ~,,ertise~enl. P~?molio.n ~r ~ale of~!~: ~rodt~I or P~?Cess, ~r in ?>"":<=.tion \\'!th ~ r~·ptJWicaJton of"1his repon SAMPLE SUMMARY American West Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday ANALYTICAL LABORATORIES Project: 2nd Quarter Chloroform 2020 Lab Set ID: 2005695 Date Received: 5/29/2020 1050h Lab Sample ID Client Sample ID Date Collected Matrix Analysis 3440 South 700 West 2005695-00JA TW4-25 05272020 5/27/2020 915h Aqueous Anions, E300.0 ~alt Lake City, UT 84119 2005695-001 B TW4-25_05272020 5/27/2020 915h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-001 C TW4-25 05272020 5/27/2020 915h Aqueous VOA by GC/MS Method 8260D/5030C Phone: (801) 263-8686 2005695-002A TW4-24 05272020 5/27/2020 925h Aqueous Anions, E300.0 2005695-002B TW4-24 05272020 5/27/2020 925h Aqueous Nitrite/Nitrate (as N), E353.2 Toll Free: (888) 263-8686 2005695-002C TW4-24 05272020 5/27/2020 925h Aqueous VOA by GC/MS Method Fax:(801)263-8687 8260D/5030C :-mail: awal@awal-labs.com 2005695-003A TW4-40 05272020 5/27/2020 1245h Aqueous Anions, E300.0 2005695-003B TW4-40 05272020 5/27/2020 1245h Aqueous Nitrite/Nitrate (as N), E353.2 web: www.awal-labs.com 2005695-003C TW4-40 05272020 5/27/2020 1245h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-004A TW4-39 05272020 5/27/2020 1002h Aqueous Anions, E300.0 Kyle F. Gross 2005695-004B TW4-39 05272020 5/27/2020 1002h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-004C TW4-39 05272020 5/27/2020 1002h Aqueous VOA by GC/MS Method Laboratory Director 8260D/5030C 2005695-005A TW4-21 05272020 5/27/2020 905h Aqueous Anions, E300.0 Jose Rocha 2005695-005B TW4-21 05272020 5/27/2020 905h Aqueous Nitrite/Nitrate (as N), E353.2 QA Officer 2005695-005C TW4-21 05272020 5/27/2020 905h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-006A TW4-04 05272020 5/27/2020 1222h Aqueous Anions, E300.0 2005695-006B TW4-04 05272020 5/27/2020 1222h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-006C TW4-04 05272020 5/27/2020 1222h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-007 A MW-26 05272020 5/27/2020 1010h Aqueous Anions, E300.0 2005695-007B MW-26 05272020 5/27/2020 1010h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-007C MW-26_05272020 5/27/2020 1010h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-008A TW4-0l 05272020 5/27/2020 1205h Aqueous Anions, E300.0 2005695-008B TW4-0l 05272020 5/27/2020 1205h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-008C TW4-0l 05272020 5/27/2020 1205h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-009A TW4-41 05272020 5/27/2020 1215h Aqueous Anions, E300.0 2005695-009B TW4-41 05272020 5/27/2020 1215h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-009C TW4-41 05272020 5/27/2020 1215h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-01 OA MW-04 05272020 5/27/2020 1037h Aqueous Anions, E300.0 Report Date: 6/12/2020 Page 2 of 48 All anal~ ses applicable to lhe CWA. SOWA. and RCRA are performed m accordance lo NELAC protocols Pertinent sampling information is located on U1e auached COC Confiden1ial Business lnfonm1tion: This repor1 is pro\'ided for the t.\"ttushr use of 1he ~cldressee Pri, ile~es o_f sub~seq~enl ~,~e of the ~~e of this .con:ipany or an) 1~mber or ils slaff, or reproduclio~ ~r this repo~ in ~on~ecfion~ with the a~,·ertisement p~~motio.n o_• ~ale or ?-1!): -~rcx:h~t or P~?Cess, ~r in ~onn~c!ion w~lh th~ r~-pubHea1fon or 1his report Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday Project: 2nd Quarter Chloroform 2020 American West Lab Set ID: 2005695 ANALYTICAL LAB0RAT0Rlf6 Date Received: 5/29/2020 1050h Lab Sample ID Client Sample ID Date Collected Matrix Analysis 2005695-0lOB MW-04 05272020 5/27/2020 1037h Aqueous Nitrite/Nitrate (as N), E353.2 3440 South 700 West 2005695-01 oc MW-04 05272020 5/27/2020 1037h Aqueous VOA by GC/MS Method 8260D/5030C ;alt Lake City, UT 84119 2005695-01 lA TW4-02 05272020 5/27/2020 1028h Aqueous Anions, E300.0 2005695-01 IB TW4-02 05272020 5/27/2020 1028h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-01 lC TW4-02 05272020 5/27/2020 1028h Aqueous VOA by GC/MS Method Phone: (801)263-8686 8260D/5030C 2005695-012A TW4-ll 05272020 5/27/2020 1020h Aqueous Anions, E300.0 Toll Free: (888) 263-8686 2005695-012B TW4-ll 05272020 5/27/2020 1020h Aqueous Nitrite/Nitrate (as N), E353.2 Fax:(801)263-8687 2005695-012C TW4-11 05272020 5/27/2020 1020h Aqueous VOA by GC/MS Method :-mail: awal@awal-Jabs.com 8260D/5030C 2005695-013A TW4-22 05272020 5/27/2020 935h Aqueous Anions, E300.0 web: www.awal-labs.com 2005695-013B TW4-22 05272020 5/27/2020 935h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-013C TW4-22 05272020 5/27/2020 935h Aqueous VOA by GC/MS Method 8260D/5030C Kyle F. Gross 2005695-014A TW4-19 05272020 5/27/2020 845h Aqueous Anions, E300.0 2005695-0148 TW4-19_05272020 5/27/2020 845h Aqueous Nitrite/Nitrate (as N), E353.2 Laboratory Director 2005695-0 l 4C TW4-19_05272020 5/27/2020 845h Aqueous VOA by GC/MS Method 8260D/5030C Jose Rocha 2005695-015A TW4-37 _05272020 5/27/2020 945h Aqueous Anions, E300.0 QA Officer 2005695-0 l 5B TW4-37 05272020 5/27/2020 945h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-0 l 5C TW4-37 05272020 5/27/2020 945h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-016A TW4-20 05272020 5/27/2020 952h Aqueous Anions, E300.0 2005695-0168 TW4-20 05272020 5/27/2020 952h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-016C TW4-20 05272020 5/27/2020 952h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-017 A TW4-60 05272020 5/27/2020 1310h Aqueous Anions, E300.0 2005695-0178 TW4-60 05272020 5/27/2020 1310h Aqueous Nitrite/Nitrate (as N), E353.2 2005695-0 l 7C TW4-60 05272020 5/27/2020 1310h Aqueous VOA by GC/MS Method 8260D/5030C 2005695-018A Trip Blank 5/27/2020 845h Aqueous VOA by GC/MS Method 8260D/5030C Report Date: 6/12/2020 Page 3 of 48 All ano.l)ses applicable to the CWA. SDWA. and RCRA are perfonned in accordance to NELAC protocols. Pertinenl sampling information is localed on the attached COC Conlidenlia\ Business Information: This report is prO\•ided for the exclusi\"e use of the ~ddressee Pri, ile~es o.r su~seq~ent ~e of lhe ~~ne of this .con:-JX!ny or an) ,~mber of its slafl';. or reproducli<H~ ~f lhis repo~ in ~o~ection .. \\·ilh lhe n1,•ertise~enl. P~?molio.n ~r ~aJe of~~~: rrodt~ct or p~~ss, ~r in ~nn~!ion \\'!th th: r~·publication of this report American West ANALYTICAL LABORATORIES 3440 South 700 West ;alt Lake City, UT 84119 Phone:(801)263-8686 Toll Free: (888) 263-8686 Fax: (801) 263-8687 :-mail: awal@awal-labs.com web: www.awal-labs.com Kyle F. Gross Laboratory Director Jose Rocha QA Officer Inorganic Case Narrative Client: Contact: Energy Fuels Resources, Inc. Tanner Holliday Project: Lab Set ID: Sample Receipt Information: Date of Receipt: Date(s) of Collection: Sample Condition: C-0-C Discrepancies: 2nd Quarter Chloroform 2020 2005695 5/29/2020 5/27/2020 Intact None Holding Time and Preservation Requirements: The analysis and preparation of all samples were performed within the method holding times. All samples were properly preserved. Preparation and Analysis Requirements: The samples were analyzed following the methods stated on the analytical reports. Analytical QC Requirements: All instrument calibration and calibration check requirements were met. All internal standard recoveries met method criterion. Batch QC Requirements: MB, LCS, MS, MSD, RPD: Method Blanks (MB): No target analytes were detected above reporting limits, indicating that the procedure was free from contamination. Laboratory Control Samples (LCS): All LCS recoveries were within control limits, indicating that the preparation and analysis were in control. Matrix Spike / Matrix Spike Duplicates (MS/MSD): All percent recoveries and RPDs (Relative Percent Differences) were inside established limits, indicating no apparent matrix interferences. Corrective Action: None required. Report Date: 6/12/2020 Page 4 of 48 All anal~ ses applicable lo the CWA. SDWA. and RCRA are perfom1ed m accordance lo NELAC protocols Pertinent sampling infomtalion is located on the atlached COC Confidential Business lnformation: This repo/1 is pro,,ided for lhe('xclusn·c-use of the ~ddressee Pri, ile~es o.r sub~seq~enl ~~e of the ~~1e of this .co11:1pa11y or an~ ~mber or iLS slaff, or reproduclio~ ~f lhis repo~ in ~on~eclion ... ,,.i1h the n~vertisemenl P~?molio.n ~· ~aJe of ?1!Y .. ~rodt)cl or P~?Cess, ~r in 7onn~c~ion w(lh th~ r~-p~blu:n1ion or 1his report ANALYTICAL Client: Energy Fuels Resources, Inc. Lab Set ID: 2005695 Project: 2nd Quarter Chlorofonn 2020 Analyte Result Units 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, To\1 Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com C SUMMARY REPORT Contact: Dept: Tanner Holliday WC Method MDL Reporting Limit QC Type: LCS Amount Spiked Spike Ref. Amount %REC Lab Sample ID: LCS-Rl39685 Date Analyzed: 06/09/2020 1438h Test Code: 300.0-W Chloride 5.20 mg/L E300.0 0.0565 0.100 5.000 0 104 Lab Sample ID: LCS-Rl39343 Date Analyzed: 06/01/2020 1401h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.05 mg/L E353.2 0.00494 0.0100 1.000 0 105 Limits 90 -110 90 -110 Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPD Ref. RPD Limit Amt %RPD Qual Report Date: 6/12/2020 Page 41 of 48 analyses applicable to the CWA. SOWA, and RCRA are performed in accordance to NELAC protocols Pertinent sampling information is located on the attached COC Confidential Business Information: This report is provided for the exclusive use of the addressee Privileges of subsequent use oft~ ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee will be granted only on contact Thls ANALYTICAL Client: Energy Fuels Resources, Inc. Lab Set ID: 2005695 Project: 2nd Quarter Chloroform 2020 Analyte Result Lab Sample ID: MB-RI39685 Date Analyzed: Test Code: 300.0-W Chloride < 0.100 Lab Sample ID: MB-R139343 Date Analyzed: Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) < 0.0100 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, Toll Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com C SUMMARY REPORT Contact: Dept: QC Type: Reporting Amount Spiked Units Method MDL Limit 06/09/2020 1421h mg/L E300.0 0.0565 0.100 06/01/2020 1400h mg/L E353.2 0.00494 0.0100 Tanner Holliday WC MBLK Spike Ref. Amount %REC Limits Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPD Ref. RPD Amt %RPO Limit Qual Report Date: 6/12/2020 Page 42 of 48 analyses applicable to the CWA. SDWA, and RCRA are perfonned in accordance to NELAC protocols Pertinent sampling information is located on the attached COC' Confidential Business Tnfonnation: This report is provided for the exclusive use of the addressee. Privileges of subsequent use of tl- ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee will be granted only on contact, This ANALYTICAL Client: Energy Fuels Resources, Inc. Lab Set ID: 2005695 Project: 2nd Quarter Chloroform 2020 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, Toll Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com _Q__C SUMMARY REPORT Contact: Dept: QC Type: Tanner Holliday WC MS ---- Analyte Result Units Method Lab Sample ID: 2005695-00JAMS Date Analyzed: 06/09/2020 1545h Test Code: 300.0-W Chloride 86.9 mg/L E300,0 Lab Sample ID: 2005695-006AMS Date Analyzed: 06/09/2020 1759h Test Code: 300.0-W Chloride 94.7 mg/L E300.0 Lab Sample ID: 2005695-00IBMS Date Analyzed: 06/01/2020 1414h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.82 mg/L E353.2 MDL 0.565 0.565 0.00494 Reporting Limit 1.00 1.00 0.0100 Amount Spiked Spike Ref. Amount 50.00 36.5 50.00 46.1 1.000 0.851 %REC Limits 101 90 -110 97.2 90 -110 97.2 90 -110 Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPDRef. RPD Limit Amt %RPO Qual Report Date: 6/12/2020 Page 43 of 48 analyses applicable to the CWA. SOWA, and RClv\ ore perromicd in accordan<:< to NELAC protocols Pertinent sampling information is located on the attached COC Confidential Business Information: This report is provided for the exclusive use of the addressee Privileges of subsequent use of tt ne of this company or any member of its staff, or rcproduct1on or this report in c.onnect1on wuh Lhc advertisement. promotion or sale of any product or process. or in connection with the re-publication of this report for any purpose other than for the addressee wlll be granted on]y on contact Thls 3440 South 700 West Salt Lake City, UT 84119 Phone: (801) 263-8686, Toll Free: (888) 263-8686, Fax: (801) 263-8687 e-mail: awal@awal-labs.com, web: www.awal-labs.com QC SUMMARY REPORT Client: Energy Fuels Resources, Inc. Contact: Tanner Holliday WC Lab Set ID: 2005695 Project: 2nd Quarter Chloroform 2020 Analyte Result Units Method Lab Sample ID: 2005695-00JAMSD Date Analyzed: 06/09/2020 1602h Test Code: 300.0-W Chloride 86.9 mg/L E300.0 Lab Sample ID: 2005695-006AMSD Date Analyzed: 06/09/2020 1816h Test Code: 300.0-W Chloride 95.8 mg/L E300.0 Lab Sample ID: 2005695-00IBMSD Date Analyzed: 06/01/2020 1415h Test Code: N02/N03-W-353.2 Nitrate/Nitrite (as N) 1.82 mg/L E353.2 MDL 0.565 0.565 0.00494 Reporting Limit 1.00 1.00 0.0100 Dept: QC Type: MSD Amount Spiked Spike Ref. Amount %REC 50.00 36.5 IOI 50.00 46.1 99.4 1.000 0.851 96.8 Limits 90 -110 90 -110 90 -110 Kyle F. Gross Laboratory Director Jose Rocha QA Officer RPO Ref. RPO Limit Amt %RPO 86.9 0.0629 20 94.7 1.12 20 1.82 0.220 10 Qual Report Date: 6/12/2020 Page 44 of 48 analyses applicable to the CWA. SDWA, and RCRA are perfonned in accordance to NE LAC protocols Pertinent sampling information is located on the attached COC Confidential Business Information: This report is provided for the exclusive use of the addressee. Privileges of subsequent use of tl- ne of this company or any member of its staff, or reproduction of this report in connection with the advertisement. promotion or sale of any product or process, or in connection with the re-publication of this report for any purpose other than for the addressee will be granted only on contact This American West Analytical Laboratories Rpt Emailed: WORK ORDER Summary Client: Client ID: Project: Energy Fuels Resources, Inc. ENE300 2nd Quarter Chloroform 2020 Contact: Tanner Holliday QC Level: III Work Order: 2005695 Due Date: 6/12/2020 WO Type: Project Comments: QC 3 (no chromatograms). EDD-Denison. CC KWeinel@energyfuels.com; Do not use "*R_" samples as MS/MSD.; Jd Sample ID Client Sample ID Collected Date Received Date Test Code Matrix Set Storage 2005695-00IA TW 4-25 _ 05272020 5/27/2020 0915h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analy_tes: CL 2005695-00IB N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 2005695-00IC 8260D-W-DEN100 VOCFridge Test Group_: 826()_D~W-DENIOO:_# of Analytes: 41 # of Su": 4 2005695-002A TW4-24_05272020 5/27/2020 0925h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analytes: CL 2005695-002B N02/N03-W-353.2 df-no2/no3 I SELAnalftes: N03N02N 2005695-002C 8260D-W~DEN100 VOCFridge Test Groll/): 8260D-W-DENI 00; # of Ana/ytes: 4 j # of Surr: 4 2005695-003A TW 4-40 ~05272020 5/27/2020 1245h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analyres: CL 2005695-00JB N02/N03-W-353.2 elf-no2/no3 1 SEL Analyres: N03N02N 2005695-00JC 8260D-W-DEN100 VOCFridge Test 'Group_: 8260D-W-DEN I 00; # of Analytes: 41 # of Surr: 4 2005695-004A TW4-39_05272020 5/27/2020 1002h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analftes: CL 2005695-004B N02/N03-W-353.2 df. no2/no3 I SEL Analytes: N03N02N 2005695-004C 8260D-W-DEN100 VOCFridge Test Group_: 8260D-~D§li_lOO; # of Analytes: 41 # ofSurr: 4 2005695-00SA TW4-21_05272020 5/27/2020 0905h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analytes: CL 2005695-005B N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 2005695-00SC 8260D-W-DEN100 VOCFridge Test GrouF_: 8260D-W-DENIOO; # of Anaj)'_les: 41 # of Surr: 4 UL Denison Page I of4 3 3 3 3 3 Printed: 05/29/20 13:38 LABORATORY CHECK: %M D RT D CN O TAT O QC O LUO 0 HOK ___ HOK __ _ HOK___ COG Emailed,___ ___ _ WORK ORDER Summary Work Order: 2005695 Page 2 of4 Client: Energy Fuels Resources, Inc. Due Date: 6/12/2020 Sample ID Client Sample ID Collected Date Received Date Test Code Matrix Sel Storage 2005695-006A T\V4-04_05272020 5/27/2020 1222h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes: CL 2005695-006B N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 2005695-006C 8260D-W-DEN100 VOCFridge 3 Test Group: 8260D-W-DENJOO; # of Analytes: 4/# ofSurr: 4 2005695-007A l\'I\V-26_05272020 5/27/2020 1010h 5/29/2020 1 OS Oh 300.0-W Aqueous elf-we I SEL Analytes: CL 2005695-007B N02/N03-W-353.2 elf. no2/no3 I SEL Analytes: N03N02N 2005695-00?C 8260D-W-DEN100 VOCFridge 3 Test Group: 8260D-W-DENJOO; # of Analytes: 4 I # ofSurr: 4 2005695-00&A T\V4-01_05272020 5/27/2020 1205h 5/29/2020 1050h 300.0-W Aqueous df-we I SEL Analytes: CL 2005695-00&B N02/N03-W-353.2 elf. no2/no3 I SEL Analytes: N03N02N 2005695-00SC 8260D-W-DEN100 VOCFridge 3 .. ; ·'. :: .. · .. · Test Group: 8260D-W-J?ENJOO; # of Analytffc.S,-.4 /.# of Surr: 4 2005695-009A T\V4-41_05272020 5/27/2020 1215h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes: CL 2005695-009B N02/N03-W-353.2 elf-no2/no3 I SEL Analytes: N03N02N 2005695-009C ~ ., ·-8260D-W•DEN100 VOCFridge 3 Test Group: 8260D-W-DENIOO; # of Analytes: 4/# ofSurr: 4 2005695-0lOA l\tW-04_05272020 5/27/2020 1037h 5/29/2020 1050h 300.0-W Aqueous elf. we I SEL Analytes: CL 2005695-0lOB N02/N03-W-353.2 elf. no2/no3 I SEL Analytes: N03N02N 2005695-0lOC 8260D-W-DEN100 VOCFridge 3 Test Gro11p: 8260D-W-DENJOO; # of Analytes: 4/#ofSurr: 4 2005695-0llA T\V4-02_05272020 5/27/2020 1028h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes:· CL 2005695-01 lB N02/N03-W-353.2 elf. no2/no3 I SEL Analytes: N03N02N 2005695-01 lC 8260D-W-DEN100 VOCFridge 3 Test Group: 8260D-W-DENJ 00; # of Analytes: 4 I# of Surr: 4 --- Printed: 05/29/20 13:38 LABORATORY CHECK: %M 0 RTO CNO TAT D aco LUOO HOK __ HOK __ HOK __ COG Emailed WORK ORDER Summary Client: Energy Fuels Resources, Inc. Sample ID Client Sample ID 2005695-012A TW4-11_05272020 2005695-012B 2005695-012C 2005695-0BA TW4-22_05272020 2005695-0BB 2005695-0BC 2005695-014A TW4-19_05272020 2005695-014B '·2005695-014C ' .•.. 2005695-0 I SA TW4-37_05272020 2005695-0ISB 2005695-0 I SC 2005695-0I6A TW4-20_05272020 2005695-0 l 6B 2005695-0I6C 2005695-017 A TW4-60_05272020 2005695-0 l 7B Work Order: 2005695 Due Date: 6/12/2020 Collected Date Received Date Test Code Matrix Sel Storage 5/27/2020 1020h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes: CL N02/N03-W-353.2 elf-no2/no3 I SEL Analytes: N03N02N 8260D-W-DEN100 VOCFridge Test Group: 8260D-W-DENI 00; # of A11alytes: 41 # of Surr: 4 5/27/2020 0935h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes: CL N02/N03-W-353.2 elf-no2/no3 I SEL A11alytes: N03N02N 8260D-W-DEN100 VOCFridge Test Group: 8260D-W-DENJ 00; # of Analytes: 41 # of Surr: 4 5/27/2020 0845h 5/29/2020 1050h 300.0-W Aqueous elf-we 1 SEL Analytes: CL N02/N03-W-353.2 df-no2/no3 I SEL Analytes: N03N02N 8260D-W-DEN100 • _VOCFridge . .. , ' -Test:Oroup: 8260D-W-DENI 00; # of Analytes: 41 _lj_o[ Surr; 4 5/27/2020 0945h 5/29/2020 1050h 300.0-W Aqueous elf-we I SEL Analytes: CL N02/N03-W-353.2 df • no2/no3 I SEL Analytes: N03N02N 8260D-W-DEN100 VOCFridgc Test GrouE_: 8260D-Jf-DENI 00;...!_of A11alytes: 41 # of_Surr: 4 5/27/2020 0952h 5/29/2020 1050h 300.0-W Aqueous df-wc I SEL Analytes: CL N02/N03-W-353.2 elf-no2/no3 I SEL Analytes: N03N02N 8260D-W-DEN100 VOCFridge Test Group: 8260D-W-DENI 00; # of Analytes: 41 # of Surr: 4 5/27/2020 1310h 5/29/2020 1050h 300.0-W Aqueous df-wc 1 SEL Analytes: CL N02/N03-W-353.2 df-no2/no3 I SEL AnalJ,_tes: N03N02N Page 3 of 4 3 3 3 3 3 Printed: 05/29/20 13:38 LABORATORY CHECK: %M O RT O CN O TAT O QC O LUO 0 HOK ___ HOK __ _ HOK___ COC Emailed'------ WORK ORDER Summary Client: Energy Fuels Resources, Inc. Sample ID Client Sample ID 2005695-0l 7C 1'¥4-60_05272020 2005695-018A Trip Blank Work Order: 2005695 Due Date: 6/12/2020 Collected Date Received Date Test Code Matrix Sel Storage 5127/2020 1310h 5129/2020 1050h 8260D-W-DEN100 Aqueous VOCFridge Test Group: 8260D-W-DENJOO; # of Analytes: 41 # ofSurr: 4 5127/2020 0845h 5129/2020 1050h 8260D-W-DEN100 Aqueous VOCFridge Test GrouE_: 8260D-W-DENJOO; # <J/,4.nalytes: 41# o[Surr: 4 Page4 of4 3 3 Printed: 05(29/20 13:38 LABORATORY CHECK: %M O RT O CN O TAT O QC O LUO D HOK ___ HOK __ _ HOK___ COC Emailed'------ 2 4 American West Analytical Laboratories 463 W. 3600 S. Salt Lake City, UT 84115 Phone#(801)2~86 Toi Free# (888)263-8686 L~ Fax# (801 J 263-8687 Email awal@awaHabs.com www.awal-labs.com Client: Energy Fuels Resources, Inc. Address: 6425 S. Hwy. 191 Blanding, UT 84511 Contact: Tanner Holliday Phone#: (435) 678-2221 Cell#: gpaiiiiei@e,iergyfii.aJs.com; KWeinel@energyftteJa.com; Emai: thomclaJ@lenanfa.eta.com Project Name: 2nd Quarter Chloroform 2020 Project#: PO#: Sampler Name: Tanner Holliday Date Sample ID: Samoled TW4-25_05272020 5/27/2020 TW4-24_05272020 6/27/2020 TW4-40_05272020 5/27/2020 TW4-39 _05272020 5/27/2020 TW4-21_05272020 5/27/2020 TW'4-04_05272020 5/27/2020 MW-26_05272020 5/27/2020 TW4-01_05272020 5/27/2020 TW4-41_05272020 6/27/2020 10 l MW-04_05272020 5/27/2020 I TW4-02_05272020 5/27/2020 12 1 TW4-11_05272020 5/27/2020 13 I TW4-22_05272020 5/27/2020 1:=~by: -'-·-_ I1 I/./ A/ Dalo: <l'>IIJ'Xr!)( l T,mo: PrinlNamo: T ilMel' Hotllclov 110! RollOQUlohod l>y: Ooto: Slo.noluro TllT1r. iPrl!IIN""'°' Retlnqulehod by: Oalo: lsmnauro Time: >rtntNamo: ~oJlnqwshod l>y: Dato: Slcmatum lime: PrWNnme: I Time Sampled 915 925 1245 1002 905 1222 1010 1205 1215 1037 1028 1020 935 Reoelvodby: Slanature PrtntNeme: CHAIN OF CUSTODY All analy<I• Will be conducted using NELAP accredited methods and ell data wlll be reported using AWAl..'s otendard analyto llets end reporting llmfts (PQL) unless spedlicelJy requested olhe!v.;se on lhis Chain ol Ctlstody and/or attached dorumenlallon. QC Level: I Turn Around Time: Unless other arrangements have been made, oigned reports will be emailed by 5:00 pm on 3 Standard the day they are due. X Include EDD: LOCUS UPLOAD EXCEL Field Filtered For: for Compliance With: D NELAP D RCRA D CWA D SOWA D ELAP/A2LA o' D NLLAP ~ ci D Non-Compliance ei 0 O' D Other. !:l. "l ~ >< .. 0 "' 0 IC C ·c C') ·.; 1ii i 0 C'l C: ::;; 0 ~ Known Hazards l/) 0 " ...... ~ .. (.) C. N t) & 0 E 0 0 g .. 2: Samele Comments .. tJJ 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X 5 w X X X Date: Special Instructions: rnma: l (!~fr tS AWAL Lab Sample Set# Page 1 of 2 I°"""' I Laboratory Use Only SemplesWota,I). f'5 1 e handdelive<ed 2 Amblenta<6 3 Temperature M___ •c 4 Received Bmkervl.eaklng (lmprope~y Sealed@ y N 5 &: Pr858fVed y N . et bench y N 6 Received Within GldlngTimes N r.nc Tepe We,s: 1 ~ on O<terPaclcage Y N NA 2 ~ on Outer Padcege Y N NA 3 Present on Sample a y N 4 Unbroken on Sample G ) Y N NA Olsaepancles Between Sample Labels and COC Record?~ y N -od by: __,,?: / j_/Jo .....Lt. _/ 08!0'5 /p '7' /z. (I See the Analytical Scope of Work for Reporting Limits and voe SlgnotiJI~ • .• A analyte list. p -/1,,, -1-C_ "/ rr,me: PrintNorno: /14.L ·_,,, 1 U5t\ Received by: ' / :Cate: Signature Time: PrintNama: Received by: 1uate: Slgnetun, rnme: Print Name: American West Analytical Laboratories 463 W. 3600 S. Salt Lake C~y. UT 84115 Phone# (801) 263-8686 Toll Free# (888) 263-8686 L-~ Fax# (801) 263-8687 Email awal@awal-labs.com www.awal-labs.com Client: Energy Fuels Resources, Inc. Address: 6425 S. Hwy. 191 Blanding, UT 84511 Contact: Tamier Holliday Phone#: (435) 678-2221 Cell#: .iiialmer@eDergytl,eLi.com; XWeine1'.@enerOfaels.com; Email: thollida~1>.6i1Jfuals.com Project Name: 2nd Quarter Chloroform 2020 Project#: PO#: Sampler Name: TaD.D.er Holliday Date Samole ID: Samoled I TW4-19_05272020 5/27/2020 : TW4-37 .... 05272020 5/27/2020 f TW4-20 __ 05272020 5/27/2020 i TW4-60 __ 05272020 5/27/2020 TRlPBLANK 5/27/2020 I I ) I ! 3 RolinqlJ!ahod by: _ \#.Juu ... If ~// -/ Oele: ,,.,.,_....,,,. rnme: Prlnl Mamo: TanM'HollldoY 1100 Rellnqulohed by: Date: Slnnawn, rrime; PrinlNamo: ""'~by: Dela: ~i:se Ttme: .... -. F<elinqui•hed by: Date: Signatur& Timo: l'r1n!Netne; I Time Samoled 845 945 952 1310 845 Received by: oalurv Prlo!Name: CHAIN OF CUSTODY Al onalysls will be conducted using NEUIP acctedlted methods and all data will be ropo,ted using AWAf.'s standard analyta Ysts and reportJng llmlts (PQL) unless specifically requasled other!Mse on \his Chain or Custody and/or attached documentation. QC Level: I Tum Around Time: Unless other arrangements have been made, signed reports will be emailed by 5:00 pm on 3 Standard tho day they are due. X Include EDD: LOCUS UPLOAD EXCEL Field Filtered For: For Compliance With: D NELAP 0 RCRA 0 CWA 0 SOWA 0 ElAP/A2LA Cl 0 NLLAP ~ ci D Non-Compliance i;i 0 O' D Other: "' I!! ~ .. 0 " X 0 IO C: ·c: l'l ~ .; 0 0 ~ ::!: 0 ~ Known Hazards :z; Lt) 0 " ...... ::t. • 0 15.. C'II tJ & 0 E 0 u g ., Samole Comments "' f/l :z; 5 w X X X 5 w X X X s w X X X 5 w X X X 3 w X Date: Special Instructions: :Ttme: zGo5G?S AWAL Lab Sample Set# Page 2 of 2 I"'""" I Laboratory Use Only Sa!nplesWero: \J. V'5 ~j pposl 0< lwld cklllvmld 2 Am~o~ 3 TompendJJr• !...:.!.!._ •c 4 Received Broken/Leaking (Improperly Sealed) _ y v 5 ctr: Preserved y N at bench y N 6 Received Within Holding Times CJ' N ~CT-Was: 1 a on Outer Package N NA 2~ on Ouler Padcage . Y N NA 3 Present on Sample (5J y N 4 Unbroken on sample 6 y N niscrepancies -Sample Labels ;nd coc Recortl?d R~~ dt.. Sl!ln&lore · " A l,'vL-,..__ ...-.., / Oete· ;; , .A s ;,..."i' z..(l See the Analytical Scope of Work for Reporting Limits and voe analyte list. ~ . ./(/vi l- (J __ .,,/ Time: /(' ~l~ l'rlo!Name: t--1-.,,../, . , c=c Received by: I raate: Slanalme 1Tlme: Pr1n1Name: Received by: Date: Slnneture Time: Print Name: Analysis Ammonia COD Cyanide Metals NOz/N03 O&G Phenols Sulfide TKN TP04 CrVI+ Procedure: Frequency: Preservation Check Sheet s amp le Set E Preservative I )_ ,, l/ < (s ,_) pH<2H2S04 pH<2H2S04 pH>12NaOH pH<2HN03 pH<2H2S04 V,, ,/_,5 i//s 0_, Vr5 1/,, ( oH<2HCL I' ~ , , pH<2H2S04 pH>9NaOH, Zn Acetate oH <2H2S04 pH <2H2S04 pH>9 (NH4)2S04 Pour a small amount of sample in the sample lid Pour sample from lid gently over wide range pH paper Do Not dip the pH paper in the sample bottle or lid dpH 7 ~ ib5 0s , "I I V I I lk5 'kS WJ , 1) 2) 3) 4) 5) 6) 7) If sample is not preserved, properly List its extension and receiving pH in the appropriate column above Flag COC, notify client ifrequested Place client conversation on COC Samples may be adjusted All samples requiring preservation * + ... # • The sample required additional preservative upon receipt. The sample was received unpreserved. The sample was received unpreserved and therefore preserved upon receipt. The sample pH was unadjustable to a pH < 2 due to the sample matrix. The sample pH was unadjustable to a pH> __ due to the sample matrix interference . Lab Set ID: 2 0 0.5 (o YS pH Lot #: {pl 9 7 /,t., n I'-/ I'S /& 17 it.,; ~s-V,, f J.t s ~$ 1M- " TabH Quality Assurance and Data Validation Tables H-1 · Field QA/QC Evaluation 1x Casing 2x Casing Location Volume Volume Pumped Volume Volume Check Conductivity RPD PIEZ-01 1.66 3.32 okay 2300 NC PIEZ-02 2.26 4.52 okay 853.1 NC PIEZ-03A 0.94 1.88 okay 1135 NC TWN-01 24.97 66.00 49.94 okay 894.0 897.0 0.34 TWN-02 NA C0ntinu0uslv Pumped well --2112 NC llWN.~03· 34,8$ ·44;00 ,69i86 Purm,e.a·orv .2214 ,22BfJ i(f.26 ... TWN-04 42.80 110.00 85.6 okay 1036 1034 0.19 -TWN-l07 16,97 16)50 _ 33.~ P-urrioed·G;y 1184 1790 '0i34' TWN-18 55.49 132.00 110.98 okay 2659 2660 0.04 TW4-22 NA Continuously Pumped well --5326 NC TW4-24 NA Continuously Pumped well --7951 NC TW4-25 NA Continuously Pumped well -2514 NC r:4·22, TW4-24, TW4-25, TWN-02 are continually_pu~ wells. N-03. TWN~07 were-oummed drv and samoled after. ver:v. NM = Not Measured. The OAP does not require the measurement of redox potential or turbidity in wells that were purged to dryness. RPO= Relative Percent Difference pH RPD Temperature RPD Redox RPD Turbidity 6.55 NC 15.28 NC 351 NC 5.6 6.74 NC 15.35 NC 335 NC 0.8 6.78 NC 15.94 NC 376 NC 5.7 6.50 6.51 0.15 15.28 15.25 0.20 366 365 0.27 9.2 I 9.2 6.15 NG 15.22 NC 416 NC 0 ·a.so 6,a3 0.46 1Si24 15.20 0,26 NM 11.,:e NM 6.57 6.58 0.15 14.85 14.83 0.13 383 384 0.26 1.6 I 1.7 5.9() 5.Q~ o;ea: 16.0() 15.97 Qf'J9.' N ,f -J;{O NM ·- 6.19 6.19 0.00 14.55 14.57 0.14 347 346 0.29 1.2 I 1.2 7.24 NC 16.48 NC 348 NC 0 7.08 NC 16.00 NC 347 NC 25.0 7.12 NC 16.05 NC 311 NC 0 The OAP states that turbidity should be less than 5 Nephelometric Turbidity Units ("NTU") prior to sampling unless the well is characterized by water that has a higher turbidity. The OAP does not require that turbidity measurements be less than 5 NTU prior to sampling. As such, the noted observations regarding turbidity measurements less than 5 NTU are included for information purposes only. RPD Dissolved Oxygen RPD NC 63.0 NC NC 23.5 NC NC 90.0 NC 0.00 62.0 61.0 1.63 NC 91.0 NC l,i t;Je .. --.N M -NO' .. 6.06 65.9 65.8 0.15 -I NO --~ M _ NG - 0.00 1.1 1.1 0.00 NC 90.3 NC NC 19.4 N€ NC 42.0 NC 1 -0 lllf 1me va uat1on H 2 H ld. T' E 1 Allowed Hold Time Hold Time Hold Time Location ID Parameter Name Sample Date Analysis Date (Days) (Days) Check PIEZ-01 Chloride 5/20/2020 6/5/2020 16 28 OK PIEZ-01 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK PIEZ-02 Chloride 5/20/2020 6/5/2020 16 28 OK PIEZ-02 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK PIEZ-03A Chloride 5/20/2020 6/5/2020 16 28 OK PIEZ-03A Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-01 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-01 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-02 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-02 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-03 Chloride 5/21/2020 6/5/2020 15 28 OK TWN-03 Nitrate/Nitrite (as N) 5/21/2020 5/29/2020 8 28 OK TWN-04 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-04 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-07 Chloride 5/21/2020 6/5/2020 15 28 OK TWN-07 Nitrate/Nitrite (as N) 5/21/2020 5/29/2020 8 28 OK TWN-18 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-18 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-18R Chloride 5/20/2020 6/5/2020 16 28 OK TWN-18R Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TW4-22 Chloride 5/27/2020 6/9/2020 13 28 OK TW4-22 Nitrate/Nitrite (as N) 5/27/2020 6/1/2020 5 28 OK TW4-24 Chloride 5/27/2020 6/9/2020 13 28 OK TW4-24 Nitrate/Nitrite (as N) 5/27/2020 6/1/2020 5 28 OK TW4-25 Chloride 5/27/2020 6/9/2020 13 28 OK TW4-25 Nitrate/Nitrite (as N) 5/27/2020 6/1/2020 5 28 OK TW4-60 Chloride 5/27/2020 6/9/2020 13 28 OK TW4-60 Nitrate/Nitrite (as N) 5/27/2020 6/1/2020 5 28 OK TWN-60 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-60 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK TWN-65 Chloride 5/20/2020 6/5/2020 16 28 OK TWN-65 Nitrate/Nitrite (as N) 5/20/2020 5/29/2020 9 28 OK H-3: Analytical Method Check Paraiµettr Method Method rrsed by Lab Nitrate E353. l or E353.2 E353.2 A4500-Cl B or A4500-CI E Chloride or E300.0 E300.0 Both Nitrate and Chloride were analyzed with the correct analytical method. H-4 Reportin~ Limit Check Required Lab Reporting Dilution Reporting RL Location Analvte Limit Units Q.ualifier, Factor Limit Check PIEZ-01 Chloride I mg/L 10 1 OK PIEZ-01 Nitrate/Nitrite (as N) 0.1 mg/L 10 0.1 OK PIEZ-02 Chloride I mg/L 5 I OK PIEZ-02 Nitrate/Nitrite (as N) 0.1 mg/L 1 0.1 OK PIEZ-03A Chloride 1 mg/L 10 I OK PIEZ-03A Nitrate/Nitrite (as N) 0.1 mg/L 10 0.1 OK TWN-01 Chloride 1 mg/L 5 I OK TWN-01 Nitrate/Nitrite (as N) 0.1 mg/L 2 0.1 OK TWN-02 Chloride 1 mg/L 10 I OK TWN-02 Nitrate/Nitrite (as N) 0.5 mg/L 50 0.1 OK TWN-03 Chloride 2 mg/L 20 I OK TWN-03 Nitrate/Nitrite (as N) 0.2 mg/L 20 0.1 OK TWN-04 Chloride 1 mg/L 5 1 OK TWN-04 Nitrate/Nitrite (as N) 0.1 mg/L 2 0.1 OK TWN-07 Chloride 1 mg/L 10 I OK TWN-07 Nitrate/Nitrite (as N) 0.1 mg/L 10 0.1 OK TWN-18 Chloride I mg/L 10 I OK TWN-18 Nitrate/Nitrite (as N) 0.1 mg/L 1 0.1 OK TWN-18R Chloride 1 mg/L u I I OK TWN-18R Nitrate/Nitrite (as N) 0.1 mg/L u 1 0.1 OK TWN-60 Chloride I mg/L u I I OK TWN-60 Nitrate/Nitrite (as N) 0.1 mg/L u I 0.1 OK TW4-22 Chloride 5 mg/L 50 I OK TW4-22 Nitrate/Nitrite (as N) 0.5 mg/L 50 0.1 OK TW4-24 Chloride 10 mg/L 100 I OK TW4-24 Nitrate/Nitrite (as N) 0.5 mg/L 50 0.1 OK TW4-25 Chloride 2 mg/L 20 I OK TW4-25 Nitrate/Nitrite (as N) 0.1 mg/L I 0.1 OK TW4-60 Chloride 1 mg/L u I I OK TW4-60 Nitrate/Nitrite (as N) 0.1 mg/L u I 0.1 OK TWN-65 Chloride 1 mg/L 10 1 OK TWN-65 Nitrate/Nitrite (as N) 0.1 mg/L 2 0.1 OK H-5 QA/QC Evaluation for Sample Duplicates Constituent TW,JN~04 TWN-65 %RPD Chloride 25.1 25.4 1.19 Nitrogen 1.75 1.71 2.31 H-6 QC Control Limits for Analysis and Blanks Method Blank Deteclions All Method Blanks for the quarter were non-detect. M atrix Spike ~ Recovery Compari on All Matrix Spikes were within acceptance limits for the quarter. Laboratory Control Sample All Laboratory Control Samples were within acceptance limits for the quarter. H7R . T -ece1p1 emperature E 1 va uat10n Sampl~ Batch Wells in Batch Temoerature 2005623 PIEZ-01, PIEZ-02, PIEZ-03A, TWN-1, TWN-2, TWN-3, TWN-4, 0.7 °C TWN-7, TWN-18, TWN-18R, TWN-60, TWN-65 2005695 TW4-22, TW4-24, TW4-25, TW4-60 1.0 °C H-8 Rinsate Evaluation All rinsate and DI blank samples were non-detect for the quarter. Tab I Kriged Current Quarter Isoconcentration Maps NS = not sampled; ND= not detected MW-24A installed during December, 2019 ....._10 TW4-42 ¢3.2 TW4-40 .2.9 MW-38 -9-15 MW-32 e ND TW4-7 0 4.1 TWN-1 <>2.2 PIEZ-1 r. 7 kriged nitrate isocon and label temporary perched monitoring well installed April, 2019 showing concentration in mg/L temporary perched monitoring well installed February, 2018 showing concentration in mg/L perched monitoring well installed February, 2018 showing concentration in mg/L perched monitoring well showing concentration in mg/L temporary perched monitoring well showing concentration in mg/L temporary perched nitrate monitoring well showing concentration in mg/L perched piezometer showing concentration in mg/L •b&ndonad .. lWN-05 \ \ r1l 1mile u • MW-22 NOTES: MW-4, MW-26, TW4-1, TW4-2, TW4-4, TW4-11, TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are HYDRO GEO CHEM, INC. !&--&-------· KRIGED 2nd QUARTER, 2020 NITRATE (mg/L) (NITRATE + NITRITE AS N) WHITE MESA SITE APPROVED DATE REFERENCE FIGURE H:/718000/aug20/nitrate/Unt0620.srf 1-1 NS = not sampled; ND = not detected MW-24A installed during December, 2019 '-100 kriged chloride isocon and label TW4-42 ¢23 TW4-40 .37 MW-38 ~45 MW-32 • 36 TW4-7 0 44 TWN-1 ~33 PIEZ-1 -i 68 temporary perched monitoring well installed April, 2019 showing concentration in mg/L temporary perched monitoring well installed February, 2018showing concentration in mg/L perched monitoring well installed February, 2018 showing concentration in mg/L perched monitoring well showing concentration in mg/L temporary perched monitoring well showing concentration in mg/L temporary perched nitrate monitoring well showing concentration in mg/L perched piezometer showing concentration in mg/L abandonld • lWl'I~ . ~ . ~- 1 mUe ,11;a ....... ~1f! .58 ,..;_~ NOTES: MW-4, MW-26, TW4-1, TW4-2, TW4-4, TW4-11 , TW4-19, TW4-20, TW4-21, TW4-37, TW4-39, TW4-40 and TW4-41 are chlorofonn pumping wells; TW4-22, TW4-24, TW4-25 and TWN-2 are nitrate pumping wells . HYDRO GEO KRIGED 2nd QUARTER, 2020 CHLORIDE (mg/L) WHITE MESA SITE CHEM, INC. APPROVED DATE REFERENCE FIGURE H :/718000/aug20/chloride/Ucf0620.srf 1-2 TabJ Analyte Concentrations over Time Piezometer 1 Date Nitrate (mg/I) Chloride (mg/I) 2/19/2009 6.8 NA 7/14/2009 6.8 60 9/22/2009 7.3 78 10/27/2009 7.4 61 6/2/2010 7.2 52 7/19/2010 6.8 52 12/10/2010 6.5 60 1/31/2011 7 60 4/25/2011 6.8 58 7/25/2011 7 53 10/19/2011 6.6 55 1/11/2012 7.1 78 4/20/2012 6.6 58 7/27/2012 7.2 56 10/17/2012 7.66 55 2/18/2013 8.11 56.7 4/24/2013 8.88 53.3 8/28/2013 7.83 55.1 10/16/2013 6.68 54.1 1/13/2014 6.79 56.2 5/7/2014 7.57 52.1 8/6/2014 5.1 55 10/8/2014 5.75 57.6 2/18/2015 6.41 55.9 5/12/2015 5.95 57.5 8/26/2015 4.96 64.2 10/14/2015 6.17 54.4 2/23/2016 8.31 56.5 5/17/2016 6.33 59.1 7/19/2016 6.78 53.9 10/11/2016 6.42 58.1 2/15/2017 6.75 54.5 6/1/2017 6.60 54.7 7/20/2017 6.80 58.0 10/4/2017 6.21 54.4 1/17/2018 6.35 55.3 5/9/2018 6.56 58.0 8/8/2018 6.66 63.5 11/20/2018 6.70 55.5 2/19/2019 6.72 56.8 5/30/2019 6.75 59.4 8/14/2019 6.81 61.1 10/16/2019 7.21 59.3 1/30/2020 7.12 68.9 Piezometer 1 Date Nitrate (mg/I) 5/20/2020 6.95 Chloride (mg/I) 67.7 Piezometer 2 Date Nitrate (mg/I) Chloride (mg/I) 2/19/2009 0.500 NA 7/14/2009 0.500 7.0 9/22/2009 0.500 17.0 10/27/2009 0.600 7.0 6/2/2010 0.600 8.0 7/19/2010 0.600 8.0 12/10/2010 0.200 6.0 1/31/2011 0.300 9.0 4/25/2011 0.300 8.0 7/25/2011 0.100 9.0 10/19/2011 0.100 8.0 1/11/2012 0.100 9.0 4/20/2012 0.200 8.0 7/27/2012 0.200 9.0 10/17/2012 0.192 9.5 2/19/2013 0.218 9.7 4/24/2013 0.172 10.3 8/28/2013 0.198 9.7 10/16/2013 0.364 9.2 1/13/2014 0.169 11.4 5/7/2014 0.736 11.4 8/6/2014 0.800 12.0 10/8/2014 0.755 12.2 2/18/2015 0.749 12.6 5/12/2015 0.646 13.1 8/26/2015 0.662 15.5 10/14/2015 0.692 13.3 2/23/2016 0.615 13.4 5/17/2016 0.665 14.0 7/19/2016 0.669 12.4 10/11/2016 0.732 13.4 2/15/2017 0.696 12.4 6/1/2017 0.345 13.2 7/20/2017 0.555 13.4 10/4/2017 0.684 12.7 1/17/2018 0.716 13.0 5/9/2018 0.776 14.0 8/8/2018 0.818 15.1 11/20/2018 0.648 12.3 2/19/2019 0.599 12.9 5/30/2019 0.702 12.6 8/14/2019 0.606 13.2 10/16/2019 0.573 12.6 1/30/2020 0.740 14.2 Piezometer 2 Date 5/20/2020 Nitrate (mg/I) 0.679 Chloride (mg/I) 14.4 Piezometer 3A Date Nitrate (mg/I) Chloride (mg/I) 5/17/2016 8.23 109 7/19/2016 8.83 93.8 10/11/2016 8.44 100 2/15/2017 10.00 111 6/1/2017 10.10 124 7/20/2017 9.31 105 10/4/2017 9.65 107 1/17/2018 8.61 94.3 5/9/2018 8.98 100 8/8/2018 12.1 122 11/20/2018 11.8 105 2/19/2019 11.8 102 5/30/2019 11.8 104 8/14/2019 10.7 96.2 10/16/2019 8.97 83.0 1/30/2020 10.5 99.5 5/20/2020 12.4 88.3 TWN-1 Date Nitrate (mg/I) Chloride (mg/I) 2/6/2009 0.7 19 7/21/2009 0.4 17 9/21/2009 0.4 19 10/28/2009 0.5 18 3/17/2010 0.5 17 5/26/2010 0.6 20 9/27/2010 0.6 19 12/7/2010 0.6 14 1/26/2011 0.5 17 4/20/2011 0.5 19 7/26/2011 0.5 14 10/17/2011 0.5 10 1/9/2012 0.6 15 4/18/2012 0.6 17 7/24/2012 0.6 17 10/15/2012 0.432 17.5 2/18/2013 0.681 17.6 4/23/2013 0.84 17.4 8/27/2013 1.24 24.1 10/16/2013 1.61 26.8 1/14/2014 1.47 29.2 5/6/2014 1.63 31.1 8/5/2014 1.7 28 10/8/2014 1.46 27.6 2/18/2015 1.37 27.8 5/13/2015 0.65 29.2 8/25/2015 0.324 33.2 10/13/2015 1.35 27.7 2/23/2016 1.51 30.3 5/17/2016 1.73 32.1 7/20/2016 1.76 29.6 10/6/2016 1.98 33.0 2/15/2017 2.06 31.2 6/1/2017 1.89 32.7 7/19/2017 2.07 31.2 10/4/2017 1.95 32.0 1/18/2018 1.86 30.4 5/8/2018 2.06 28.4 8/8/2018 1.97 34.2 11/20/2018 1.98 28.9 2/20/2019 2.10 31.4 5/29/2019 1.93 32.6 8/14/2019 2.15 30.3 10/16/2019 2.35 32.0 1/29/2020 2.24 33.8 TWN-1 Date 5/20/2020 Nitrate (mg/I) 2.24 Chloride (mg/I) 33.0 TWN-2 Date Nitrate (mg/I) Chloride (mg/I) 2/6/2009 25.4 29 7/21/2009 25 25 9/21/2009 22.6 17 11/2/2009 20.8 55 3/24/2010 62.1 85 6/2/2010 69 97 9/29/2010 69 104 12/9/2010 48 93 2/1/2011 43 93 4/28/2011 40 85 7/28/2011 33 74 10/20/2011 33 76 1/12/2012 31 86 4/20/2012 48 103 7/31/2012 54 93 10/17/2012 22.1 79 2/19/2013 57.3 80.5 4/24/2013 57.7 82.1 8/27/2013 80 75.9 10/16/2013 111 70.4 1/13/2014 42.6 72.4 5/7/2014 44.7 84.9 8/6/2014 42 80 10/8/2014 70.6 81 2/18/2015 48.6 84.8 5/12/2015 52.8 82.6 8/25/2015 49.7 87.8 10/14/2015 44.9 74.9 2/23/2016 86.3 73.9 5/17/2016 45.4 74.5 7/19/2016 35.3 68.8 10/11/2016 32.6 69.8 2/15/2017 27.4 65.8 6/1/2017 25.0 61.5 7/20/2017 23.9 64.2 10/4/2017 31.9 60.5 1/19/2018 19.6 57.1 5/9/2018 19.8 62.3 8/8/2018 18.6 61.5 11/20/2018 19.6 56.0 2/19/2019 19.0 50.7 5/29/2019 45.1 102 8/14/2019 23.2 50.7 10/16/2019 18.2 53.0 1/29/2020 16.5 66.1 TWN-2 Date Nitrate (mg/I) 5/20/2020 16.1 Chloride (mg/I) 59.6 TWN-3 Date Nitrate (mg/I) Chloride (mg/I) 2/6/2009 23.6 96 7/21/2009 25.3 96 9/21/2009 27.1 99 11/2/2009 29 106 3/25/2010 25.3 111 6/3/2010 26 118 7/15/2010 27 106 12/10/2010 24 117 2/1/2011 24 138 4/28/2011 26 128 7/29/2011 25 134 10/20/2011 25 129 1/12/2012 25 143 4/20/2012 24 152 7/31/2012 27 158 10/17/2012 12.1 149 2/19/2013 22.2 157 4/24/2013 27.2 158 8/28/2013 20.9 171 10/17/2013 23.5 163 1/15/2014 19.6 160 5/7/2014 23.6 168 8/6/2014 19.5 174 10/9/2014 19.1 153 2/19/2015 19.4 164 5/14/2015 17.2 141 8/26/2015 16.2 156 10/14/2015 16.3 129 2/24/2016 16.8 128 5/18/2016 13.5 116 7/19/2016 16.8 110 10/7/2016 15.8 113 2/16/2017 17.4 113 6/2/2017 15.9 108 7/20/2017 15.9 106 10/5/2017 15.6 111 1/19/2018 14.4 107 5/9/2018 16.4 115 8/9/2018 19.4 149 11/21/2018 20.1 123 2/21/2019 20.7 140 5/30/2019 18.7 137 8/15/2019 19.8 133 10/17/2019 19.6 126 1/30/2020 19.4 156 TWN-3 Date Nitrate (mg/I) Chloride (mg/I) 5/21/2020 24.0 136 TWN-4 Date Nitrate (mg/I) Chloride (mg/I) 2/6/2009 1.00 13.0 7/21/2009 0.05 12.0 9/21/2009 0.40 13.0 10/28/2009 0.40 11.0 3/16/2010 0.90 22.0 5/27/2010 1.00 22.0 9/27/2010 0.90 19.0 12/8/2010 1.00 21.0 1/25/2011 0.90 21.0 4/20/2011 0.90 21.0 7/26/2011 1.10 35.0 10/18/2011 0.90 20.0 1/9/2012 0.90 20.0 4/18/2012 1.10 24.0 7/25/2012 1.40 25.0 10/15/2012 1.45 26.4 2/18/2013 1.51 25.3 4/23/2013 1.63 24.4 8/27/2013 1.58 27.2 10/16/2013 1.69 29.4 1/14/2014 1.41 28.4 5/6/2014 1.55 29.6 8/5/2014 2.00 28.0 10/8/2014 1.44 30.7 2/18/2015 1.48 31.5 5/13/2015 0.73 31.9 8/25/2015 0.97 35.2 10/13/2015 1.58 28.4 2/23/2016 2.02 30.7 5/17/2016 2.97 31.7 7/20/2016 3.14 28.0 10/6/2016 3.09 31.3 2/15/2017 2.63 31.2 6/1/2017 2.37 28.6 7/19/2017 2.35 28.0 10/4/2017 2.27 27.4 1/18/2018 1.77 26.3 5/8/2018 1.86 27.7 8/8/2018 1.54 28.0 11/20/2018 1.48 22.7 2/20/2019 1.53 25.3 5/29/2019 1.51 26.5 8/14/2019 1.81 23.7 10/16/2019 2.15 25.4 1/29/2020 1.89 27.2 TWN-4 Date Nitrate (mg/I) 5/20/2020 1.75 Chloride (mg/I) 25.1 TWN-7 Date Nitrate (mg/I) Chloride (mg/I) 8/25/2009 ND 11.00 9/21/2009 ND 7.00 11/10/2009 0.10 7.00 3/17/2010 0.800 6.00 5/28/2010 1.200 6.00 7/14/2010 1.600 7.00 12/10/2010 1.000 4.00 1/27/2011 1.300 6.00 4/21/2011 1.700 6.00 7/29/2011 0.700 5.00 10/19/2011 2.200 6.00 1/11/2012 2.300 5.00 4/20/2012 1.200 6.00 7/26/2012 0.900 6.00 10/16/2012 0.641 5.67 2/19/2013 0.591 5.68 4/24/2013 1.160 5.88 8/28/2013 0.835 6.96 10/16/2013 0.986 5.70 1/15/2014 0.882 5.75 5/7/2014 0.564 5.26 8/6/2014 0.900 6.00 10/9/2014 0.968 5.93 2/19/2015 1.040 5.58 5/14/2015 0.779 6.18 8/26/2015 0.348 6.12 10/14/2015 0.672 5.84 2/24/2016 0.240 6.06 5/18/2016 0.732 6.26 7/21/2016 0.810 5.97 10/7/2016 0.698 6.17 2/16/2017 1.63 14.00 6/2/2017 3.74 29.70 7/20/2017 2.70 29.00 10/5/2017 3.58 41.40 1/19/2018 5.82 69.40 5/9/2018 10.2 94.70 8/9/2018 10.6 105 11/21/2018 11.5 104 2/21/2019 12.9 107 5/30/2019 13.5 122 8/15/2019 12.9 120 10/17/2019 14.2 119 1/30/2020 14.2 128 5/21/2020 14.6 126 TWN-18 Date Nitrate (mg/I) Chloride (mg/I) 11/2/2009 1.300 57.0 3/17/2010 1.600 42.0 6/1/2010 1.800 63.0 9/27/2010 1.800 64.0 12/9/2010 1.600 59.0 1/27/2011 1.400 61.0 4/26/2011 1.800 67.0 7/28/2011 1.800 65.0 10/18/2011 1.900 60.0 1/10/2012 1.900 64.0 4/19/2012 2.100 64.0 7/26/2012 2.300 67.0 10/16/2012 1.950 67.5 2/18/2013 2.270 68.7 4/23/2013 2.320 64.3 8/27/2013 2.040 70.4 10/16/2013 2.150 67.3 1/14/2014 2.330 68.4 5/6/2014 2.180 76.5 8/5/2014 1.800 70.0 10/8/2014 1.470 74.8 2/18/2015 1.000 73.3 5/13/2015 1.350 76.6 8/25/2015 0.350 81.3 10/13/2015 0.668 69.0 2/23/2016 0.648 67.6 5/17/2016 0.497 69.9 7/20/2016 0.100 52.7 10/6/2016 0.501 67.4 2/15/2017 0.470 62.1 6/1/2017 0.392 63.9 7/19/2017 0.419 59.0 10/4/2017 0.256 56.6 1/18/2018 0.332 53.1 5/8/2018 0.283 57.8 8/8/2018 0.348 59.7 11/20/2018 0.160 48.1 2/20/2019 0.155 46.4 5/29/2019 0.129 50.0 8/14/2019 0.181 46.9 10/16/2019 0.162 47.1 1/29/2020 0.224 51.9 5/20/2020 0.236 47.4 TW4-19 Date Nitrate (mg/I) Date Chloride (mg/I) 7/22/2002 42.80 12/7/2005 81 9/12/2002 47.60 3/9/2006 86 3/28/2003 61.40 7/20/2006 123 6/23/2003 11.40 11/9/2006 134 7/15/2003 6.80 2/28/2007 133 8/15/2003 4.00 8/15/2007 129 9/12/2003 5.70 10/10/2007 132 9/25/2003 9.20 3/26/2008 131 10/29/2003 7.70 6/25/2008 128 11/9/2003 4.80 9/10/2008 113 8/16/2004 9.91 10/15/2008 124 9/17/2004 4.50 3/4/2009 127 3/16/2005 5.30 6/23/2009 132 6/7/2005 5.70 9/14/2009 43 8/31/2005 4.60 12/14/2009 124 12/1/2005 0.10 2/17/2010 144 3/9/2006 4.00 6/9/2010 132 6/14/2006 5.20 8/16/2010 142 7/20/2006 4.30 · 10/11/2010 146 11/9/2006 4.60 2/17/2011 135 2/28/2007 4.00 6/7/2011 148 8/15/2007 4.10 8/17/2011 148 10/10/2007 4.00 11/17/2011 148 3/26/2008 2.20 1/23/2012 138 6/25/2008 2.81 6/6/2012 149 9/10/2008 36.20 9/5/2012 149 10/15/2008 47.80 10/3/2012 150 3/4/2009 3.20 2/11/2013 164 6/23/2009 2.40 6/5/2013 148 9/14/2009 0.10 9/3/2013 179 12/14/2009 26.70 10/29/2013 206 2/17/2010 2.00 1/27/2014 134 6/9/2010 4.40 5/19/2014 152 8/16/2010 5.90 8/11/2014 140 10/11/2010 2.70 10/21/2014 130 2/17/2011 17.00 3/9/2015 238 6/7/2011 12.00 6/8/2015 180 8/17/2011 3.00 8/31/2015 326 11/17/2011 5.00 10/19/2015 252 1/23/2012 0.60 3/9/2016 276 6/6/2012 2.40 5/23/2016 201 9/5/2012 2.50 7/25/2016 214 10/3/2012 4.10 10/13/2016 200 2/11/2013 7.99 3/8/2017 461 6/5/2013 2.95 6/13/2017 135 TW4-19 Date Nitrate (mg/I) Date Chloride (mg/I) 9/3/2013 17.60 7/26/2017 218 10/29/2013 4.70 10/11/2017 139 1/27/2014 1.62 3/12/2018 193 5/19/2014 1.34 6/8/2018 138 8/11/2014 1.60 8/22/2018 166 10/21/2014 4.72 11/28/2018 140 3/9/2015 8.56 3/8/2019 197 6/8/2015 0.92 6/5/2019 160 8/31/2015 11.60 9/4/2019 153 10/19/2015 10.60 12/10/2019 147 3/9/2016 15.70 2/19/2020 205 5/23/2016 1.27 5/27/2020 147 7/25/2016 10.50 10/13/2016 10.00 3/8/2017 11.10 6/13/2017 0.243 7/26/2017 1.12 10/11/2017 0.377 3/12/2018 8.61 6/8/2018 0.494 8/22/2018 2.55 11/28/2018 0.233 3/8/2019 6.58 6/5/2019 8.96 9/4/2019 0.332 12/10/2019 0.535 2/19/2020 10.10 5/27/2020 1.14 The sampling program for TW4-19 was updated in the fourth quarter of 2005 to include analysis for chloride as well as nitrate. This change accounts for the different number of data points represented above. TW4-21 Date Nitrate (mg/I) Date Chloride (mg/I) 5/25/2005 14.6 12/7/2005 353 8/31/2005 10.1 3/9/2006 347 11/30/2005 9.6 7/20/2006 357 3/9/2006 8.5 11/8/2006 296 6/14/2006 10.2 2/28/2007 306 7/20/2006 8.9 6/27/2007 327 11/8/2006 8.7 8/15/2007 300 2/28/2007 8.7 10/10/2007 288 6/27/2007 8.6 3/26/2008 331 8/15/2007 8.6 6/25/2008 271 10/10/2007 8.3 9/10/2008 244 3/26/2008 14.3 10/15/2008 284 6/25/2008 8.8 3/11/2009 279 9/10/2008 7.6 6/24/2009 291 10/15/2008 8.0 9/15/2009 281 3/11/2009 8.3 12/22/2009 256 6/24/2009 8.1 2/25/2010 228 9/15/2009 9.2 6/10/2010 266 12/22/2009 8.4 8/12/2010 278 2/25/2010 8.4 10/13/2010 210 6/10/2010 12.0 2/22/2011 303 8/12/2010 14.0 6/1/2011 297 10/13/2010 7.0 8/17/2011 287 2/22/2011 9.0 11/16/2011 276 6/1/2011 13.0 1/19/2012 228 8/17/2011 14.0 6/13/2012 285 11/16/2011 13.0 9/13/2012 142 1/19/2012 15.0 10/4/2012 270 6/13/2012 11.0 2/13/2013 221 9/13/2012 13.0 6/18/2013 243 10/4/2012 14.0 9/12/2013 207 2/13/2013 11.8 11/13/2013 206 6/18/2013 13.8 2/5/2014 200 9/12/2013 10.3 5/22/2014 243 11/13/2013 9.0 8/27/2014 230 2/5/2014 11.4 10/29/2014 252 5/22/2014 11.5 3/12/2015 255 8/27/2014 7.1 6/8/2015 494 10/29/2014 10.0 8/31/2015 499 TW4-21 Date Nitrate (mg/I) Date Chloride (mg/I) 3/12/2015 10.9 10/19/2015 413 6/8/2015 13.1 3/9/2016 452 8/31/2015 14.7 5/23/2016 425 10/19/2015 14.3 7/25/2016 457 3/9/2016 14.6 10/12/2016 439 5/23/2016 13.1 3/8/2017 478 7/25/2016 16.S 6/13/2017 309 10/12/2016 13.5 7/26/2017 447 3/8/2017 17.7 10/11/2017 378 6/13/2017 9.5 3/12/2018 447 7/26/2017 18.2 6/8/2018 387 10/11/2017 16.9 8/22/2018 182 3/12/2018 15.8 10/22/2018 392 6/8/2018 14.1 3/8/2019 180 8/22/2018 0.236 6/5/2019 456 10/22/2018 15.2 9/4/2019 478 3/8/2019 8.99 12/10/2019 339 6/5/2019 17.5 2/19/2020 446 9/4/2019 14.7 5/27/2020 353 12/10/2019 5.73 2/19/2020 8.93 5/27/2020 15.4 TW4-22 Date Nitrate (mg/I) Chloride (mg/I) 2/28/2007 20.9 347 6/27/2007 19.3 273 8/15/2007 19.3 259 10/10/2007 18.8 238 3/26/2008 39.1 519 6/25/2008 41.9 271 9/10/2008 38.7 524 10/15/2008 36.3 539 3/11/2009 20.7 177 6/24/2009 20.6 177 9/15/2009 40.3 391 12/29/2009 17.8 175 3/3/2010 36.6 427 6/15/2010 19 134 8/12/2010 18 127 8/24/2010 15 130 10/13/2010 16 134 2/23/2011 18 114 6/1/2011 17 138 8/17/2011 15 120 11/16/2011 19 174 1/19/2012 14 36 6/13/2012 12.8 35 9/12/2012 7 121 10/4/2012 14 130 2/11/2013 58 635 6/5/2013 50.2 586 9/3/2013 29.7 487 10/29/2013 45.2 501 1/27/2014 54.6 598 5/19/2014 47.2 614 8/11/2014 41.5 540 10/21/2014 54.9 596 3/9/2015 69.2 675 6/8/2015 47.1 390 8/31/2015 64.7 557 10/19/2015 56.1 567 3/9/2016 31.1 583 5/23/2016 58.4 598 7/25/2016 61.3 619 10/12/2016 61.5 588 3/8/2017 69.8 566 6/13/2017 70.8 572 7/26/2017 66.1 391 10/11/2017 80.1 600 3/12/2018 62.3 607 6/8/2018 72.5 580 TW4-22 Date Nitrate (mg/I) Chloride (mg/I) 8/22/2018 55.4 613 11/28/2018 75.7 567 3/8/2019 71.9 528 6/5/2019 83.9 662 9/4/2019 72.5 588 12/10/2019 59.9 608 2/19/2020 57.7 606 5/27/2020 60.5 578 TW4-24 Date Nitrate (mg/I) Chloride (mg/I) 6/27/2007 26.1 770 8/15/2007 29 791 10/10/2007 24.7 692 3/26/2008 24.4 740 6/25/2008 45.3 834 9/10/2008 38.4 1180 10/15/2008 44.6 1130 3/4/2009 30.5 1010 6/24/2009 30.4 759 9/15/2009 30.7 618 12/17/2009 28.3 1080 2/25/2010 33.1 896 6/9/2010 30 639 8/11/2010 32 556 8/24/2010 31 587 10/6/2010 31 522 2/17/2011 31 1100 5/26/2011 35 1110 8/17/2011 34 967 11/16/2011 35 608 1/18/2012 37 373 6/6/2012 37 355 8/30/2012 37 489 10/3/2012 38 405 2/11/2013 35.9 1260 6/5/2013 23.7 916 9/3/2013 32.6 998 10/29/2013 34.6 1030 1/27/2014 31.6 809 5/19/2014 35 1020 8/11/2014 31.5 1150 10/21/2014 35.7 1050 3/9/2015 34.6 944 6/8/2015 31.8 1290 8/31/2015 25.3 788 10/19/2015 29.6 909 3/9/2016 29.1 989 5/23/2016 24.2 771 7/25/2016 34.4 1,180 10/12/2016 31.9 1,010 3/8/2017 41.3 1,090 6/13/2017 39.9 1,080 7/26/2017 40.0 1,230 10/11/2017 31.7 895 3/12/2018 44.9 1,320 6/14/2018 33.6 792 8/22/2018 33.8 996 11/28/2018 38.4 1,100 3/8/2019 39.3 1,040 6/5/2019 33.2 1,020 9/4/2019 36.4 1,130 12/10/2019 33.8 1,090 TW4-24 Date 2/19/2020 5/27/2020 Nitrate (mg/I) 37.1 41.7 Chloride (mg/I) 1,010 1,060 TW4-25 Date Nitrate (mg/I) Chloride (mg/I) 6/27/2007 17.1 395 8/15/2007 16.7 382 10/10/2007 17 356 3/26/2008 18.7 374 6/25/2008 22.1 344 9/10/2008 18.8 333 10/15/2008 21.3 366 3/4/2009 15.3 332 6/24/2009 15.3 328 9/15/2009 3.3 328 12/16/2009 14.2 371 2/23/2010 14.4 296 6/8/2010 16 306 8/10/2010 14 250 10/5/2010 15 312 2/16/2011 15 315 5/25/2011 16 321 8/16/2011 16 276 11/15/2011 16 294 1/18/2012 16 304 5/31/2012 16 287 9/11/2012 17 334 10/3/2012 17 338 2/11/2013 9.04 190 6/5/2013 5.24 136 9/3/2013 5.69 119 10/29/2013 6.10 88.6 1/27/2014 2.16 85.7 5/19/2014 1.21 51.1 8/11/2014 1.6 67 10/21/2014 1.03 58.1 3/9/2015 14.4 310 6/8/2015 1.14 58.3 8/31/2015 1.63 69.2 10/21/2015 1.78 93.7 3/9/2016 0.837 62.7 5/23/2016 0.959 75.5 7/25/2016 1.78 74.1 10/12/2016 1.24 59.8 3/8/2017 17.0 285 6/13/2017 0.976 69.8 7/26/2017 1.23 70.1 10/11/2017 1.29 68.0 3/12/2018 2.23 70.5 6/14/2018 1.14 60.3 TW4-25 Date Nitrate (mg/I) Chloride (mg/I) 8/22/2018 0.810 69.1 11/28/2018 0.634 59.7 3/8/2019 0.639 65.0 6/5/2019 0.821 59.0 9/4/2019 0.548 58.1 12/10/2019 0.841 73.1 2/19/2020 0.607 86.0 5/27/2020 0.851 76.8 MW-30 Date Nitrate (mg/I) Date Chloride (mg/I) 6/22/2005 12.4 6/22/2005 125 9/22/2005 12.8 9/22/2005 125 12/14/2005 13.6 12/14/2005 128 3/22/2006 13.8 3/22/2006 125 6/21/2006 14.5 6/21/2006 124 9/13/2006 14.1 9/13/2006 118 10/25/2006 14.6 10/25/2006 124 3/15/2007 14.4 3/15/2007 125 8/22/2007 14.6 8/22/2007 126 10/24/2007 14.9 10/24/2007 122 3/19/2008 14.8 3/19/2008 118 6/3/2008 18.7 6/3/2008 125 8/4/2008 17.3 8/4/2008 121 11/5/2008 15.6 11/5/2008 162 2/3/2009 15.3 2/3/2009 113 5/13/2009 15.1 5/13/2009 122 8/24/2009 20.9 8/24/2009 118 10/14/2009 15.0 10/14/2009 129 1/20/2010 15.4 1/20/2010 106 2/9/2010 16.1 2/9/2010 127 4/27/2010 15.8 4/27/2010 97 5/24/2010 17.0 9/14/2010 111 6/15/2010 15.3 11/9/2010 126 8/24/2010 16.0 2/1/2011 134 9/14/2010 15.0 4/11/2011 134 10/19/2010 15.0 5/10/2011 128 11/9/2010 15.0 6/20/2011 127 12/14/2010 16.0 7/5/2011 127 1/10/2011 15.0 8/3/2011 126 2/1/2011 16.0 9/7/2011 145 3/14/2011 17.0 10/4/2011 129 4/11/2011 16.0 11/8/2011 122 5/10/2011 16.0 12/12/2011 124 6/20/2011 17.0 1/24/2012 124 7/5/2011 17.0 2/14/2012 126 8/3/2011 14.0 3/14/2012 128 9/7/2011 16.0 4/10/2012 128 10/4/2011 16.0 5/2/2012 124 11/8/2011 16.0 6/18/2012 131 12/12/2011 16.0 7/10/2012 128 1/24/2012 17.0 8/7/2012 139 2/14/2012 17.0 9/19/2012 130 MW-30 Date Nitrate (mg/I) Date Chloride (mg/I) 3/14/2012 18.0 10/23/2012 135 4/10/2012 17.0 11/13/2012 114 5/2/2012 16.0 12/26/2012 122 6/18/2012 15.0 1/23/2013 128 7/10/2012 17.0 2/26/2013 129 8/7/2012 18.0 3/20/2013 126 9/19/2012 16.0 4/17/2013 117 10/23/2012 16.2 5/15/2013 119 11/13/2012 18.5 6/25/2013 127 12/26/2012 17.2 7/10/2013 130 1/23/2013 19.2 8/20/2013 126 2/26/2013 21.4 9/18/2013 131 3/20/2013 14.3 10/22/2013 128 4/17/2013 16.8 11/20/2013 124 5/15/2013 18.8 12/18/2013 134 6/25/2013 16.1 1/8/2014 131 7/10/2013 17.6 2/25/2014 135 8/20/2013 16.4 3/11/2014 144 9/18/2013 16.9 4/23/2014 154 10/22/2013 19.7 5/14/2014 128 11/20/2013 19.5 6/3/2014 128 12/18/2013 20.7 7/29/2014 140 1/8/2014 20.3 8/20/2014 139 2/25/2014 18.4 9/9/2014 136 3/11/2014 21.3 10/7/2014 136 4/23/2014 18.3 11/10/2014 154 5/14/2014 17.9 12/10/2014 138 6/3/2014 19.4 1/21/2015 144 7/29/2014 15.6 2/4/2015 136 8/20/2014 13.8 3/3/2015 132 9/9/2014 16.8 4/8/2015 142 10/7/2014 11.0 5/12/2015 145 11/10/2014 16.2 6/24/2015 142 12/10/2014 17.1 7/7/2015 145 1/21/2015 19.5 8/11/2015 165 2/4/2015 14.9 9/15/2015 165 3/3/2015 17.3 10/7/2015 137 4/8/2015 17.0 11/11/2015 140 5/12/2015 16.1 12/9/2015 144 6/24/2015 15.8 1/20/2016 143 7/7/2015 15.3 2/10/2016 145 8/11/2015 17.9 3/2/2016 142 MW-30 Date Nitrate (mg/I) Date Chloride (mg/I) 9/15/2015 17.3 4/13/2016 144 10/7/2015 19.1 5/4/2016 139 11/11/2015 16.3 6/14/2016 142 12/9/2015 18.2 7/13/2016 137 1/20/2016 14.6 8/18/2016 150 2/10/2016 20.0 9/14/2016 146 3/2/2016 17.8 10/5/2016 148 4/13/2016 18.0 11/3/2016 143 5/4/2016 17.3 12/6/2016 158 6/14/2016 18.S 1/18/2017 150 7/13/2016 16.1 2/2/2017 150 8/18/2016 18.0 3/6/2017 250 9/14/2016 17.0 4/5/2017 146 10/5/2016 17.2 5/2/2017 146 11/3/2016 18.0 6/5/2017 153 12/6/2016 18.2 7/11/2017 160 1/18/2017 19.0 8/14/2017 173 2/2/2017 17.4 9/12/2017 149 3/6/2017 20.4 10/5/2017 153 4/5/2017 18.3 11/1/2017 156 5/2/2017 17.5 12/6/2017 159 6/5/2017 18.8 1/23/2018 152 7/11/2017 16.2 2/22/2018 158 8/14/2017 19.2 3/8/2018 167 9/12/2017 18.7 4/12/2018 145 10/5/2017 18.8 5/15/2018 174 11/1/2017 17.4 6/19/2018 169 12/6/2017 18.3 7/24/2018 177 1/23/2018 15.2 8/10/2018 170 2/22/2018 17.6 9/11/2018 183 3/8/2018 17.0 10/22/2018 140 4/12/2018 17.3 11/14/2018 166 5/15/2018 17.7 12/11/2018 154 6/19/2018 16.9 1/16/2019 157 7/24/2018 17.4 2/13/2019 167 8/10/2018 18.7 3/6/2019 160 9/11/2018 18.0 4/9/2019 138 10/22/2018 17.3 5/7/2019 175 11/14/2018 16.9 6/3/2019 165 12/11/2018 17.2 7/16/2019 181 1/16/2019 17.9 8/6/2019 190 2/13/2019 18.2 9/24/2019 176 MW-30 Date Nitrate (mg/I) Date Chloride (mg/I) 3/6/2019 16.2 10/8/2019 170 4/9/2019 18.5 11/13/2019 180 5/7/2019 17.9 12/4/2019 185 6/3/2019 15.8 1/15/2020 182 7/16/2019 19.3 2/5/2020 187 8/6/2019 15.8 3/11/2020 182 9/24/2019 17.9 4/6/2020 195 10/8/2019 18.2 5/6/2020 177 11/13/2019 17.2 6/3/2020 180 12/4/2019 17.8 1/15/2020 16.4 2/5/2020 17.8 3/11/2020 19.0 4/6/2020 18.1 5/6/2020 18.6 6/3/2020 18.3 Under the groundwater sampling program, accelerated monitoring for nitrate began in MW-30 prior to when the accelerated monitoring for chloride began. This difference accounts for the different number of data points represented above. MW-31 Date Nitrate (mg/I) Date Chloride (mg/I) 6/22/2005 24.2 6/22/2005 139 9/22/2005 22.4 9/22/2005 136 12/14/2005 23.8 12/14/2005 135 3/22/2006 24.1 3/22/2006 133 6/21/2006 25.3 6/21/2006 138 9/13/2006 24.6 9/13/2006 131 10/25/2006 25.1 10/25/2006 127 3/15/2007 23.2 3/15/2007 132 3/15/2007 22.0 3/15/2007 132 8/27/2007 23.3 8/27/2007 136 10/24/2007 24.6 10/24/2007 122 3/19/2008 25.0 3/19/2008 124 6/3/2008 29.3 6/3/2008 128 8/4/2008 28.7 8/4/2008 124 11/11/2008 29.9 11/11/2008 119 2/3/2009 23.4 2/3/2009 115 5/13/2009 22.4 5/13/2009 124 8/24/2009 15.4 8/24/2009 122 10/14/2009 22.6 10/14/2009 138 2/9/2010 21.7 2/9/2010 128 4/20/2010 22.5 4/20/2010 128 5/21/2010 23.0 9/13/2010 139 6/15/2010 21.1 11/9/2010 138 8/24/2010 22.0 2/1/2011 145 9/13/2010 21.0 4/1/2011 143 10/19/2010 20.0 5/10/2011 143 11/9/2010 20.0 6/20/2011 145 12/14/2010 20.0 7/5/2011 148 1/10/2011 19.0 8/2/2011 148 2/1/2011 21.0 9/6/2011 148 3/14/2011 22.0 10/3/2011 145 4/1/2011 21.0 11/8/2011 145 5/10/2011 20.0 12/12/2011 148 6/20/2011 22.0 1/24/2012 155 7/5/2011 22.0 2/13/2012 150 8/2/2011 20.0 3/13/2012 152 9/6/2011 21.0 4/9/2012 160 10/3/2011 21.0 5/2/2012 151 11/8/2011 21.0 6/18/2012 138 12/12/2011 21.0 7/9/2012 161 1/24/2012 21.0 8/6/2012 175 2/13/2012 21.0 9/18/2012 172 MW-31 Date Nitrate (mg/I) Date Chloride (mg/I) 3/13/2012 22.0 10/22/2012 157 4/9/2012 21.0 11/6/2012 189 5/2/2012 20.0 12/18/2012 170 6/18/2012 21.6 1/22/2013 176 7/9/2012 21.0 2/19/2013 174 8/6/2012 21.0 3/19/2013 168 9/18/2012 21.0 4/16/2013 171 10/22/2012 18.0 5/13/2013 169 11/6/2012 23.6 6/24/2013 179 12/18/2012 22.2 7/9/2013 182 1/22/2013 22.8 8/19/2013 183 2/19/2013 19.3 9/17/2013 193 3/19/2013 19.1 10/23/2013 188 4/16/2013 18.8 11/18/2013 174 5/13/2013 23.8 12/17/2013 203 6/24/2013 20.0 1/7/2014 194 7/9/2013 21.7 2/17/2014 197 8/19/2013 16.0 3/10/2014 230 9/17/2013 21.2 4/28/2014 230 10/23/2013 21.2 5/13/2014 200 11/18/2013 23.9 6/2/2014 173 12/17/2013 24.2 7/28/2014 200 1/7/2014 24.0 8/18/2014 210 2/17/2014 20.6 9/3/2014 210 3/10/2014 26.2 10/6/2014 205 4/28/2014 19.1 11/4/2014 204 5/13/2014 23.3 12/9/2014 215 6/2/2014 23.1 1/20/2015 226 7/28/2014 19.0 2/2/2015 211 8/18/2014 15.2 3/3/2015 209 9/3/2014 18.9 4/7/2015 211 10/6/2014 15.9 5/11/2015 225 11/4/2014 20.9 6/23/2015 228 12/9/2014 17.0 7/6/2015 222 1/20/2015 20.9 8/10/2015 264 2/2/2015 18.7 9/15/2015 231 3/3/2015 19.8 10/6/2015 222 4/7/2015 19.0 11/9/2015 215 5/11/2015 18.4 12/8/2015 231 6/23/2015 18.0 1/19/2016 228 7/6/2015 18.8 2/15/2016 246 8/10/2015 19.9 3/2/2016 228 MW-31 Date Nitrate (mg/I) Date Chloride (mg/I) 9/15/2015 18.9 4/12/2016 254 10/6/2015 22.0 5/3/2016 243 11/9/2015 18.4 6/15/2016 252 12/8/2015 19.5 7/12/2016 241 1/19/2016 18.9 8/16/2016 272 2/15/2016 18.8 9/13/2016 254 3/2/2016 18.0 10/4/2016 260 4/12/2016 22.8 11/1/2016 267 5/3/2016 18.6 12/5/2016 274 6/15/2016 19.2 1/17/2017 287 7/12/2016 17.4 2/7/2017 266 8/16/2016 19.7 3/6/2017 250 9/13/2016 18.6 4/4/2017 263 10/4/2016 18.8 5/1/2017 263 11/1/2016 19.8 6/5/2017 278 12/5/2016 18.5 7/11/2017 254 1/17/2017 20.9 8/14/2017 310 2/7/2017 21.1 9/11/2017 248 3/6/2017 20.4 10/2/2017 287 4/4/2017 19.5 11/1/2017 292 5/1/2017 18.3 12/4/2017 285 6/5/2017 20.8 1/24/2018 323 7/11/2017 18.0 2/20/2018 292 8/14/2017 19.5 3/5/2018 311 9/11/2017 20.2 4/17/2018 308 10/2/2017 21.0 5/14/2018 326 11/1/2017 19.2 6/18/2018 359 12/4/2017 19.2 7/23/2018 351 1/24/2018 17.0 8/10/2018 336 2/20/2018 18.8 9/10/2018 333 3/5/2018 19.0 10/24/2018 286 4/17/2018 19.0 11/13/2018 281 5/14/2018 18.8 12/10/2018 302 6/18/2018 18.0 1/15/2019 283 7/23/2018 18.0 2/12/2019 296 8/10/2018 18.3 3/5/2019 322 9/10/2018 20.1 4/10/2019 294 10/24/2018 18.3 5/7/2019 346 11/13/2018 17.9 6/3/2019 325 12/10/2018 18.3 7/15/2019 374 1/15/2019 19.0 8/5/2019 372 2/12/2019 18.6 9/23/2019 365 MW-31 Date Nitrate (mg/I) Date Chloride (mg/I) 3/5/2019 18.5 10/9/2019 318 4/10/2019 19.7 11/12/2019 338 5/7/2019 18.9 12/3/2019 343 6/3/2019 19.7 1/14/2020 381 7/15/2019 19.8 2/4/2020 370 8/5/2019 17.0 3/10/2020 368 9/23/2019 19.5 4/6/2020 376 10/9/2019 19.8 5/5/2020 361 11/12/2019 18.8 6/2/2020 377 12/3/2019 18.3 1/14/2020 17.5 2/4/2020 18.0 3/10/2020 19.2 4/6/2020 18.8 5/5/2020 20.1 6/2/2020 18.7 Under the groundwater sampling progran, accelerated monitoring for nitrate began in MW-31 prior to when the accelerated monitoring for chloride began. This difference accounts for the different number of data points represented above. TabK Concentration Trend Graphs oi-unr 6 ~-qa.:1 L~-das ti) C 0 .:. g~-kell'J ca ... -C G) u C 0 0 v~-oaa G) -ca ... • '!:: z T"" ... £ ~ -onv G) -G) E 0 N G) a. G ~ -Jdy O~-AON 60-1nr 0 co (!) I.() C\I ..-0 ..- (1/6w) u, C 0 .:; m II--C a, CJ C 0 (..) a, "'C "i: 0 .c (..) ,.... II-a, -a, E 0 N a, CL 0 0) 0 co 0 co 0 0 LO "<t (116w) 0 C'? 0 C\I 0 0 ,- OG·unr 6 ~-qa.:1 L~-das 9 ~-ABV\I v~-oaa £ ~ -onv G ~ -Jd'v' O~·AON oi-unr 6 ~-qa.:l L~-das "' r:: 0 9 ~ -li'BV\I ;; as lo, -r:: CL> (,) r:: 0 0 v ~-::>aa CL> -as lo, :t:: z C\I lo, 8 ~-5ny CL> -CL> E 0 N CL> a: G ~-Jdy O~-AON so-qa.:l 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0) CX) ,..._ co U) -.:t" C") C\I .... 0 0 0 0 0 0 (116w)0 0 0 0 0 U) C 0 .:: cu i... -C G) u C 0 0 G) "C 'i: ..2 .c 0 N i... G) -G) E 0 N G) ii: 0 <X) .... 0 co .... 0 ..,; .... C! C\J T"" C! 0 0 cx:i .... (116w) 0 co 0 ci oi-unr 6 ~-qa.:1 L~-das 9 ~-ABV\J 17~-oaa 8 ~ -6nv< G ~ -Jd'v' o~-AoN ..-----.,-----,------,-----~---~---~----,-~i-uer oi-unr 6~-oaa 6 ~ -AeV\I u, C 0 .: cu I., -C Cl) -8~-PO (.) C 0 0 Cl) -cu I., .:!:: 8~-Jd'v' z <C M I., Cl) -Cl) E 0 H-das N Cl) ll. -L ~-Jel,IIJ g ~-6ny ----+-----+-----------------+-----+ g~-uer "<t C\J 0 00 (0 C\J 0 ,-,-,- (1J6w) U) C 0 ·~ (U I., -C Cl) u C 0 0 Cl) 'C 'i: 0 .c 0 <( C') I., Cl) -Cl) E 0 N .! CL 0 """ ..... 0 C\I ..... 0 0 ..... 0 <X) (116w) 0 co 0 """ 0 C\J 0 ac~-unr 6~-oaa 6 ~-ABV\I B~-PO B~-JdV L~-das L ~ -JBV\I g~-5nv U) C 0 ·..: ca ... -C Cl) (.) C 0 0 Cl) -ca ... :t:: z ,... I z ~ U') C\J ..- t\i (1J6w) U') 0 0 oi-unr 6 ~-qa.:1 L~-das 9 ~-Ael/\l v~-:>aa 8~-Bnv- l ~ -Jd'7' o~-AoN 60-1nr fl) C 0 ; CG "--C Cl) C.) C 0 0 Cl) "C "i: 0 .&; 0 ,.... I z ;: t- 0 '<t 0 C') lO (\J 0 (\J (1,Sw) oi-unr 6 ~-qa.:1 n-das 9 ~-Aell'J v~-~aa £~-Bnv c~-JdV O~-IION 60-1nr lO 0 lO 0 ,-,- Cl) C 0 .:; m "--C Cl) u C 0 0 Cl) -m "--~ z N I z 3: I- 0 C\J ..... 0 0 ..... 0 CX) 0 (0 (1/6w) 0 C\J 0 oc-unr 6 ~-qa.:1 L~-das 9 ~-A'BV'J v~-::>aa £~-6nv G ~-JdV Q~-AON II) C 0 ; ca ... -C Ci) u C 0 0 Ci) ,, ·.::: .2 .c 0 "' I z 3: I- 0 C\I T"" 0 0 T"" 0 co 0 CD (116w) 0 C\I 0 oi-unr 6 ~-qa.:1 L~-das 9 ~ -ABV\I v~-oaa £ ~ -onv G ~-JdV Q~-AON 60-1nr U) C 0 ·..:; ca ... -C G) () C 0 0 G) -ca ... .:t:: z C") I z 3:: I- I() Cl'.) I() (\J 0 (\J (1/6w) oc-unr 6 ~-qa.:1 L~-das 9 ~ -ABV\I v~-oaa 8~-Bnv l~-JdV O~·/\ON I() 0 I() 0 T"" T"" ,n C 0 .:; co lo., -C CL) CJ C 0 0 CL) "C "i: .2 .c 0 C") I z == t- 0 0 C\I 0 co .... 0 (0 .... 0 ..._,. .... 0 C\I .... 0 0 .... (116w) 0 co 0 (0 0 ..._,. 0 C\I OG·unr 6 ~-qa.:J L~-das 9 ~-ABV\I v~-oaa 8 ~ -6nv G ~ -JdV O~·AON 0 u, C 0 ·.;:; cu ... -C Cl) u C 0 0 Cl) -cu ... :!:: z -.::t' I z == I- 0 LO (") 0 0 C') 0 LO C\i 0 0 0 LO C\i (116w) T""" 0 C! T""" 0 LO 0 0 0 0 oi-unr 6 ~-qa.::1 L~-das g ~-A'BV\I v ~-oao 8 ~-Bnv G ~ -Jd'v' O~-/\ON ,,, C 0 ; ca ... -C Cl) () C 0 0 Cl) "C 'i: 0 .c 0 ,i:t' I z ~ 0 0 s:t 0 It) C') 0 0 C') 0 It) (\J 0 0 (1j8w) 0 It) ,- 0 0 ,- 0 It) 0 0 oi-unr L~-das 9 ~-A'BV\I v~-:>aa £ ~ -onv c ~ -Jd'v' Q~-AON 60-1nr en C 0 '+:i cu ... -C G) (.) C 0 0 G) -cu ... :!:: z r--I z 3: I- 0 0 co ,- 0 0 -.:i-,- 0 0 C\i ,- 0 0 0 ,- 0 0 (11ffiii) 0 0 co 0 0 -.:i- 0 0 C\i 0 0 0 oi-unr 6 ~-qa.:1 n-das g ~-ABV\I 17~-oaa £ ~ -Bnv G ~ -Jd'v' Q~-AON 60-1nr U) C 0 ·.;; as ... -C G> u C 0 (.) G> 'C 'i: 0 ~ (.) ..... I z 3: I- 0 0 0 '<:I" .... 0 0 0 C\I .... 0 0 0 0 .... 0 0 0 0 g(,16w) g 0 0 0 '<:I" 0 0 0 C\I 0 0 0 oi-unr 6 ~-qa.:1 L~-das g ~-keV\I v~-oaa £~-5nv l~-JdV Q~-AON 60-1nr U) C 0 .:; ca I., -C Cl) u C 0 (.) Cl) -ca I., :!::: z co ,.... I z ;: I- 0 0 LO C\J 0 0 0 c\j 0 0 LO 0 0 0 (116w) T"" 0 0 LO 0 0 0 0 0 OG-unr 6 ~-qa.:1 L~-das 9 ~ -ABV\I v~-oaa 8 ~ -6nv G ~ -Jd'v' 0 ~ -/\ON 60-1nr ,n C 0 .:; ca ... -C G> u C 0 0 G> "C -~ ..2 .c 0 co T"" I z 3: I- 0 0 0) 0 0 (X) 0 0 ,...._ 0 0 co ~ 0 0 0 '° (1J6wF 0 0 C") 0 0 C\I 0 0 ~ 0 0 oc-unr 6 ~-qa.:J L~-das 9 ~ -ABV'J t> ~-::>aa £~-onv G ~-JdV O~-AON I-' N w ~ V, en -.J 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 7/22/2002 3/28/2003 7/15/2003 9/12/2003 10/29/2003 8/16/2004 3/16/2005 8/31/2005 3/9/2006 7/20/2006 2/28/2007 10/10/2007 -f 6/25/2008 ~ 10/15/2008 ~ I 6/23/2009 ~ \0 12/14/2009 z 6/9/2010 -· ,... ., 10/11/2010 DJ ,... 6/7/2011 n, 11/17/2011 n 0 6/6/2012 ::, 10/3/2012 n n, 6/5/2013 ::, ,... 10/29/2013 ., DJ 5/19/2014 ,... -· 10/21/2014 0 ::, 6/8/2015 VI 10/19/2015 5/23/2016 10/13/2016 6/13/2017 10/11/2017 6/8/2018 11/28/2018 6/5/2019 12/10/2019 5/27/2020 I-' I-' V, 0 V, 0 0 0 0 12/1/2005 5/1/2006 10/1/2006 3/1/2007 8/1/2007 1/1/2008 6/1/2008 11/1/2008 4/1/2009 9/1/2009 2/1/2010 7/1/2010 12/1/2010 5/1/2011 10/1/2011 3/1/2012 8/1/2012 1/1/2013 6/1/2013 11/1/2013 4/1/2014 9/1/2014 2/1/2015 7/1/2015 12/1/2015 5/1/2016 10/1/2016 3/1/2017 8/1/2017 1/1/2018 6/1/2018 11/1/2018 4/1/2019 9/1/2019 2/1/2020 N N 0 V, 0 0 w 0 0 w V, 0 "" 0 0 "" V, 0 V, 0 0 -4 ~ .i::. I a-,a. U) n :::r -0 ., -· C. tD n 0 ::::, n tD ::::, ,.. ., Ql ,.. -· 0 ::::, u, TW4-21 Nitrate Concentrations 20.0 -,---------------------------------------------- 18.0 ~ 16.0 ---------------------------------------.-------- 14.0 I a e • I I e a. I -\. I V I I .. II I I I 12.0 I I I I e I I I f If l f II I I I I I I 10.0 I '~ I I I I I I , I I • I I I H I I 8.0 I ,.. ~ ~~ 1/ II II II 6.0 -+----------------------------------------...... ------- 4.0 -+----------------------------------------...... ----- 2.0 --------------------------------------------- 0.0 ---.-------.------.------.-----....--------,.-----.---""T""""--..-------,--~----.----.........---------,r----, # # # # # ~ ~ ~ ~ ~ ~ # ~ # ~ # ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ... .... "' w """ V, °' 0 0 0 0 0 0 0 0 0 0 0 0 0 12/1/2005 5/1/2006 10/1/2006 3/1/2007 8/1/2007 1/1/2008 6/1/2008 11/1/2008 4/1/2009 9/1/2009 2/1/2010 7/1/2010 -I 12/1/2010 :e ~ 5/1/2011 I N 10/1/2011 a-,a, n 3/1/2012 ::r -8/1/2012 0 .., -· 1/1/2013 a. 6/1/2013 t1) n 11/1/2013 0 ::::, 4/1/2014 n t1) 9/1/2014 ::::, ,... 2/1/2015 .., DJ ,... 7/1/2015 -· 0 12/1/2015 ::::, "' 5/1/2016 10/1/2016 3/1/2017 8/1/2017 1/1/2018 6/1/2018 11/1/2018 4/1/2019 9/1/2019 2/1/2020 7/1/2020 12/1/2020 5/1/2021 "' C 0 ·-.., ~ .., C CV u C 0 u CV .., tU ... .., ·-z N N I -.::t' ~ I- 0 Cl) 0 00 0 " 0 I.O 0 0 LI') o::t 1/Sw 0 ("() 0 N 0 2/28/2007 6/27/2007 8/15/2007 10/10/2007 3/26/2008 6/25/2008 9/10/2008 10/15/2008 3/11/2009 6/24/2009 9/15/2009 12/29/2009 3/3/2010 6/15/2010 8/12/2010 8/24/2010 10/13/2010 2/23/2011 6/1/2011 8/17/2011 11/16/2011 1/19/2012 6/13/2012 9/12/2012 10/4/2012 2/11/2013 6/5/2013 9/3/2013 10/29/2013 1/27/2014 5/19/2014 8/11/2014 10/21/2014 3/9/2015 6/8/2015 8/31/2015 10/19/2015 3/9/2016 5/23/2016 7/25/2016 10/12/2016 3/8/2017 6/13/2017 7/26/2017 10/11/2017 3/12/2018 6/8/2018 8/22/2018 11/28/2018 3/8/2019 6/5/2019 9/4/2019 12/10/2019 2/19/2020 5/27/2020 0 I-' 0 0 N 0 0 w 0 0 mg/L .,::. 0 0 l/1 0 0 a, 0 0 "" 0 0 00 0 0 -I :E ~ I N N n :::r -0 ""I -· Q. tD n 0 ::::, n tD ::::, rt' Dl rt' -· 0 ::::, u, TW4-24 Nitrate Concentrations so 45 40 35 30 ... bD 25 E 20 15 10 5 0 ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ef#~~~~i~~~~#~~ef~ffe~ffe~~~~~~i~ <o\ ~r::,\ <o\ ~r::,\ <o\ 4'-<o ~ ~ (b\ ~ (b\ ~ °> ~ (b\ '>:, (b\ '>:, "' '>:, "' ,,,, (b\ '>:, °> ~ .... bD E TW4-24 Chloride Concentrations 1400 1200 1000 800 600 400 200 0 ~ ~ ~ ~ ~ ~ ~ ~ y y ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~~~~~~~~~~~~~~~~~~~~~~~~~~~ &~&~&N~~NN~~N~NN~~~\~~\~~«~~~ ~ ~ ~ ~ ~ ~ ~ V ~ ~ ~ V ~ ~ ~ ~ ~ ~ ~ V ...I tio E TW4-25 Nitrate Concentrations 25 20 15 10 5 0 ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ y y ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~~~~~~~~~~~~~~~~~~~~~~~~~~~ i~P~~f~~p~~&~~1P~P~~~~~~~~~ ~ ~ ~ ~ ~ v ~ ~ v ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ v v ~ u, C 0 ·-..., ~ ..., C (U u C 0 u (U "'C ·i: 0 .c u a.n N I ~ ~ I- 0 0 "'" 0 U"'I l'l"I 0 0 m 0 LI') N 1/Sw 0 0 N 0 LI') ......, 0 0 ......, 0 U"'I 0 I-' I-' N N 0 V, 0 V, 0 V, b b b b b b 6/22/2005 6/21/2006 8/22/2007 8/4/2008 8/24/2009 4/27/2010 9/14/2010 1/10/2011 5/10/2011 9/7/2011 1/24/2012 5/2/2012 s 9/19/2012 1/23/2013 ~ I 5/15/2013 w 9/18/2013 0 1/8/2014 z -· 5/14/2014 .... al 9/9/2014 .... 1/21/2015 tD n 5/12/2015 0 9/15/2015 ::, n 1/20/2016 tD 5/4/2016 ::, .... 9/14/2016 al .... 1/18/2017 -· 0 5/2/2017 ::, 9/12/2017 &I> 1/23/2018 5/15/2018 9/11/2018 1/16/2019 5/7/2019 9/24/2019 1/15/2020 5/6/2020 Under the. I-' I-' N N w V, 0 V, 0 V, 0 0 0 0 0 0 0 0 6/1/2005 12/1/2005 6/1/2006 12/1/2006 6/1/2007 12/1/2007 6/1/2008 12/1/2008 6/1/2009 s: 12/1/2009 :E 6/1/2010 I w 12/1/2010 0 n 6/1/2011 :::r -12/1/2011 0 ~ 6/1/2012 -· a. 12/1/2012 tD n 6/1/2013 0 ::::J 12/1/2013 n tD 6/1/2014 ::::J ,... 12/1/2014 ~ DJ 6/1/2015 ,... -· 12/1/2015 0 ::::J 6/1/2016 V, 12/1/2016 6/1/2017 12/1/2017 6/1/2018 12/1/2018 6/1/2019 12/1/2019 6/1/2020 0 V, 0 0 ~ 0 0 ~ V, 0 N 0 0 N V, 0 w 0 0 w u, 0 6/22/2005 +--~~t--~---t~~~~~--;-~----::::;ai.t-~~-i--~-----1 3/22/2006 10/25/2006 8/27/2007 6/3/2008 2/3/2009 10/14/2009 5/21/2010 9/13/2010 12/14/2010 3/14/2011 6/20/2011 9/6/2011 12/12/2011 3/13/2012 6/18/2012 9/18/2012 12/18/2012 3/19/2013 6/24/2013 9/17/2013 12/17/2013 3/10/2014 6/2/2014 9/3/2014 12/9/2014 3/3/2015 6/23/2015 9/15/2015 12/8/2015 3/2/2016 6/15/2016 9/13/2016 12/5/2016 3/6/2017 6/5/2017 9/11/2017 12/4/2017 3/5/2018 6/18/2018 9/10/2018 12/10/2018 3/5/2019 6/3/2019 9/23/2019 12/3/2019 3/10/2020 6/2/2020 s ~ I w ~ z -· ,... ""I QJ ,... t1) n 0 ::::, n t1) ::::, ,... cil ,... -· 0 ::::, V, 6/1/2005 11/1/2005 4/1/2006 9/1/2006 2/1/2007 7/1/2007 12/1/2007 5/1/2008 10/1/2008 3/1/2009 8/1/2009 1/1/2010 6/1/2010 11/1/2010 4/1/2011 9/1/2011 2/1/2012 7/1/2012 12/1/2012 5/1/2013 10/1/2013 3/1/2014 8/1/2014 1/1/2015 6/1/2015 11/1/2015 4/1/2016 9/1/2016 2/1/2017 7/1/2017 12/1/2017 5/1/2018 10/1/2018 3/1/2019 8/1/2019 1/1/2020 6/1/2020 0 V, 0 .... 0 0 .... V, 0 N 0 0 N V, 0 w 0 0 w V, 0 ~ 0 .i,. V, 0 s: ~ I w .... n :::r -0 .., -· Q, 11) n 0 j n 11) j ,... ol ,... -· 0 j "' TabL CSV Transmittal Letter Kathy Weinel From: Sent: To: Cc: Subject: Attachments: Mr. Goble, Kathy Weinel Monday, August 17, 2020 8:21 AM Phillip Goble Dean Henderson; Terry Slade; Scott Bakken; Logan Shumway; David Frydenlund; Paul Goranson Transmittal of CSV Files White Mesa Mill 2020 Q2 Nitrate Monitoring 2005623-report-EDD.csv; Q2 2020 DTW all programs.csv; Q2 2020 Field Data.csv Attached to this e-mail is an electronic copy of laboratory results for nitrate monitoring conducted at the White Mesa Mill during the second quarter of 2020, in Comma Separated Value (CSV) format. Please contact me at 303-389-4134 if you have any questions on this transmittal. Yours Truly Kathy Weinel (eF --·-· Energy Fuels Resources (USA) Inc. Kathy Weinel Quality Assurance Manager t: 303.389.4134 It: 303.389.4125 225 Union Blvd., Suite 600 Lakewood, CO 80228 http://www.energyfuels.com This e-mail is intended for the exclusive use of person(s) mentioned as the recipient(s). This message and any attached files with it are confidential and may contain privileged or proprietary information. If you are not the intended recipient(s) please delete this message and notify the sender. You may not use, distribute print or copy this message if you are not the intended recipient(s). 1 TabM Residual Mass Estimate Analysis Figure Tab M -Figures g G) -ca E ; II) w II) II) ca :E G) E :::, a: G) -ca .. -z 45000 -.--~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~--. 40000 I I I I · --35000 I ' I \ I\ ~ r-- 30000 25000 I 20000 +---..----,-~-r-~..------.~-,-~-r-~,-----,-~-,-~.....---,~-,-~-r-~.-----,-~-.-~.....---,~--,-~"'T""~.,....---,,~-,-~-r---,,----r~-.-~..-----.~--1 0 ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ b b b b ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~?#~~?#~~?~~~?#~~?~~~?#~??~~~? ---+---Nitrate Plume Mass Estimates ---Linear (Nitrate Plume Mass Estimates) HYDRO GEO CHEM,INC. Time Series of Nitrate Plume Mass Estimates Approved I Date SJS File Name I Figure Nmtrend4019.xls M.1 Author Date H:\718000\aug20\nitrate\masscalc\Nmtrend2Q20.xls: Fig M.1 Tab M -Tables The Residual Mass Estimate Analysis Tables Table M.1 Residual Nitrate Plume Mass residual plume quarter mass (lb) baseline 43700 01 2013 41350 02 2013 34140 03 2013 36930 04 2013 41150 01 2014 31410 02 2014 30620 03 2014 24140 04 2014 34370 01 2015 38740 02 2015 33042 03 2015 34880 04 2015 30980 01 2016 33083 02 2016 28465 03 2016 32230 04 2016 31798 01 2017 43787 02 2017 32145 03 2017 32939 04 2017 31501 01 2018 33616 02 2018 31257 03 2018 25568 04 2018 28805 01 2019 29509 02 2019 31455 03 2019 30976 04 2019 29870 01 2020 32740 02 2020 30467 Notes: lbs= pounds