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Home My WebLink AboutAppendix C Response to DWR-WQPS Comments Piedmont Lithium Carolinas, Inc. I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Updates shown in red Comments on Carolina Lithium Project by DWR-WQPS January 14. 2022 1. Chemical Processing Wastewater: The Application in section C.3.d. reflects industrial process wastewater from chemical operations will be discharged to a Publicly Owned Treatment Works (POTW) with pretreatment. Thank you for providing the requested details concerning MGD to the Long Creek WWTP. However, we still request submission of detailed chemical analysis or characterization of the wastewater. This is necessary for DWR to determine if the selected POTW has sufficient capacity to manage not only the flow volume, but the anticipated pollutant load under our rules 15A NCAC 02H section .0900. Since these comments were received, two Technical Memorandums were issued characterizing the projected flows and constituent loads for the Carolina Lithium project that are proposed to be sent to Long Creek WWTP. Please see Attachment 1 for the February 22, 2022 Technical Memorandum titled Wastewater Treatment Plant Considerations Update and the November 9, 2022 Technical Memorandum titled Carolina Lithium Wastewater Characterization. 2. Prior to issuing this Permit we believe it is in the best interest of all that Long Creek WWTP submit and secure approval from the NCDEQ DWR WQPS Municipal Permitting Unit for the anticipated increased flow to the facility. In the advent that Long Creek WWTP is unable to accept the additional flow what alternative plan does the facility operator have to manage and treat the proposed flow? In addition, an application from Long Creek WWTP will include various studies and analyses to determine if the proposed receiving water can accommodate the proposed pollutant load; including but not limited to proposed sulfate, chloride, organic carbon content and TDS. Two Rivers Utilities (TRU) have conducted studies and analysis of their Long Creek WWTP current systems. PLCI and Two Rivers Utilities have exchanged letters stating that PLCI will meet whatever limits are imposed by Two Rivers Utilities and Two Rivers Utilities has responded that they can accept PLCI's proposed volume and load as long as limits and conditions are met which are under development. Please see Attachment 2 which includes PLCI's letter to Two Rivers Utilities and Two Rivers Utilities response. 3. At this time, we believe based upon the information provided that proposed coverage under NCG02 may be inadequate to meet the operational needs of the facility. It is our position that the proposed industrial process waters potentially generated at this mine site would not have coverage under this stormwater general permit including: boiler blowdown, scrubber waste, cooling water. These wastewaters may need to be discharged under the potential POTW Significant Industrial User Permit or seek separate coverage to discharge through the NPDES program. Again, at this time we request that the applicant provide information on other wastewaters generated, including full waste characterization and Page 1 of 6 Piedmont Lithium Carolinas, Inc. I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 proposed disposal methods. Since discharges associated with "the waste rock disposal areas will be collected in ponds and subject to NPDES monitoring prior to discharge to receiving waters" at this time the applicant should apply for an NPDES discharge permit with the NCDEQ DWR WQPS IPU prior to issuance of this Permit. On December 28, 2022, PLCI submitted two separate NPDES Individual permit applications to cover stormwater associated with the site. One application covers the Lithium Mine/Concentrate Operations, and the second application covers the Lithium Hydroxide Conversion Plant. Both applications are currently under review by DWR-WQPS. 4. The information and data provided in regards to TCLP and humidity cell analyses suggests that the facility operator should secure an individual stormwater or wastewater permit to commence operations. Humidity cells are not necessarily the best way to simulate the process in mine setting and the related variation. Also, it's not known whether other real oxidation state (e.g. low DO, anoxic) would happen or not. We recommend that this option be evaluated and determined by the applicant before proceeding further. PLCI completed its' Leaching Environmental Assessment Framework (LEAF) testing and evaluated the results and its correlation to humidity cell analysis. Please see Attachment 3 to highlight the results from the above referenced testing titled LEAF and Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96) Collaboration Technical Summary. As noted in the #3 response above, PLCI submitted two separate NPDES Individual permit applications to cover stormwater associated with the site. 5. A review of the information provided did not include "Attachment 2 Concentrate Operation Drawings (Sheets 1-34) as noted in Appendix G — Response to DEMLR MRO Comments, please provide these sheets. The missing sheets as referenced can be found as Attachment 1 of this document. NOTE: The original documents included in Attachment A have been updated and are no longer the correct version to review. The updated drawings are now included as part of Appendix B — Attachment 3 of the overall response to the additional information request dated January 14, 2022. 6. The information provided in Appendix I - the Technical memo on the WWTF considerations raises a few questions that require additional clarification as follows. • We request that the facility operator [Long Creek WWTF (NC0020184)] review the November 5, 2021 Technical Memorandum and acknowledge in detail that the facility not only can accept, but can adequately handle and treat the proposed flow. This detail should be included in their letter to Piedmont Lithium. Page 2 of 6 Piedmont Lithium Carolinas,Inc.I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Long Creek WWTP has conducted their studies and analysis of their current systems. PLCI and Long Creek WWTP have continued conversations and as noted in a letter from Two Rivers Utilities dated December 2, 2021, they can accept the quantity of water PLCI proposes to send to Long Creek WWTP. PLCI and Two Rivers Utilities have exchanged letters stating that PLCI will meet whatever limits are imposed by Two Rivers Utilities and Two Rivers Utilities has responded that they can accept PLCI's proposed load as long as limits are met. Please see Attachment 2 which includes PLCI's letter to Two Rivers Utilities and Two Rivers Utilities response. • Based upon the information provided baring any pretreatment issues the wastewater system may have capacity. However, information provided did not include sufficient detail to determine if the sewer system has adequate capacity to handle the projected flow. The WWTP acceptance letter should include language that the existing sewer system has adequate capacity and an identified route for the flow in MGD. Long Creek WWTP has conducted their studies and analysis of their current systems. PLCI and Long Creek WWTP have continued conversations and as noted in a letter from Two Rivers Utilities dated December 2, 2021, they can accept the quantity of water PLCI proposes to send to Long Creek WWTP. PLCI and Two Rivers Utilities have exchanged letters stating that PLCI will meet whatever limits are imposed by Two Rivers Utilities and Two Rivers Utilities has responded that they can accept our load as long as limits are met. Gaston County has issued a Request for Qualifications (RFQ) to identify the engineering firm that will design and eventually construct the lines necessary to carry the wastewater from the PLCI site to the defined sewer system. Please see Attachment 2 which includes PLCI's letter to Two Rivers Utilities and Two Rivers Utilities response. • Based upon a review of the data provided there will be potential impact to the POTW MBAS due to oxygen transfer limits, the ability of the wastewater system to separate solids from liquids, and the potential to create overall operational issues associated with foaming. Thus, we request additional information from the applicant detailing how these concerns will be addressed. As indicated in the November 2022 Technical Memorandum, the MBAS concentration in a wastewater sample generated by simulating the Concentrator Plant process indicated a MBAS concentration of 0.43 mg/L. Surfactants are used only at the Concentrator Plant and not at the Conversion Plant. The peak design flow for the Concentrator Plant is 68.2 gpm and 123.7 gpm for the Conversion Plant. On this basis, the projected discharge concentration of MBAS from the combined streams is projected to be 0.16 mg/L. The United States Environmental Protection Agency (USEPA) secondary drinking water standard for foaming agents is 0.5 mg/L. The North Carolina FRESH SURFACE WATER QUALITY STANDARDS for all classes of water is 0.5 mg/L for MBAS. Page 3 of 6 Piedmont Lithium Carolinas, Inc. i Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Based on the above, it is expected that there is little to no risk of MBAS causing performance issues of the treatment plant. Pretreatment limits for MBAS can be placed on the PLCI discharge and PLCI will meet them via evaluating multiple options. • Additional details and supporting data are requested as to how the WWTP operator will manage the increased flow and pollutant load to ensure that biosolids utilization at the facility will not be impacted. Based on the studies completed by Long Creek WWTP and their corresponding letter, they will be able to manage the increased flow and pollutant load as long as PLCI meets the limits and conditions imposed by the future permit. • Has the applicant evaluated how the potential levels of sulfate, chloride and TDS concentrations can impact toxicity testing at the POTW? If so, please provide additional details and data on how this was determined, such as a pilot study or bench scale testing. Since these comments were received, two Technical Memorandums were issued characterizing the projected flows and constituent loads for the Carolina Lithium project that are proposed to be sent to Long Creek WWTP. Please see Attachment 1 for the February 22, 2022 Technical Memorandum titled Wastewater Treatment Plant Considerations Update and the November 9, 2022 Technical Memorandum titled Carolina Lithium Wastewater Characterization. • The information and analysis provided in the 12/15/21 response evaluates compliance with applicable Water Quality Standards; however, additional detail is required to evaluate how the facility operator will manage inhibition or sludge criteria at the plant. Please provide additional detail specifying how the plant operator will address inhibition or sludge criteria or an analysis of same. Since these comments were received, two Technical Memorandums were issued characterizing the projected flows and constituent loads for the Carolina Lithium project that are proposed to be sent to Long Creek WWTP. Please see Attachment 1 for the February 22, 2022 Technical Memorandum titled Wastewater Treatment Plant Considerations Update and the November 9, 2022 Technical Memorandum titled Carolina Lithium Wastewater Characterization. Page 4 of 6 Piedmont Lithium Carolinas, Inc. I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 7. Based upon the information provided to DWR it will be necessary to have a robust pretreatment treatment unit at the Lithium plant and the POTW will need to develop local limits. Please provide details so that DWR can evaluate. Since these comments were received, two Technical Memorandums were issued characterizing the projected flows and constituent loads for the Carolina Lithium project that are proposed to be sent to Long Creek WWTP. Please see Attachment 1 for the February 22, 2022 Technical Memorandum titled Wastewater Treatment Plant Considerations Update and the November 9, 2022 Technical Memorandum titled Carolina Lithium Wastewater Characterization. Once Long Creek WWTP provides limits and conditions, PLCI's pretreatment unit will be designed to meet such limits. The agreement to this point can be found in Attachment 2. 8. As a final note of concern the high flow wet weather data used to make assimilative capacity determinations is very optimistic. We request that assimilative capacity determinations be made based upon low flow data. Please provide the updated analyses. Since these comments were received, two Technical Memorandums were issued characterizing the projected flows and constituent loads for the Carolina Lithium project that are proposed to be sent to Long Creek WWTP. Please see Attachment 1 for the February 22, 2022 Technical Memorandum titled Wastewater Treatment Plant Considerations Update and the November 9, 2022 Technical Memorandum titled Carolina Lithium Wastewater Characterization. Page 5 of 6 Piedmont Lithium Carolinas,Inc.I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Page intentionally left blank. Page 6 of 6 Piedmont Lithium Carolinas, Inc. I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Appendix C — Attachment 1 Technical Memorandum Wastewater Treatment Plant Considerations Update (February 22, 2022) Technical Memorandum Carolina Lithium — Wastewater Characterization (November 9, 2022) Page intentionally left blank. PIEDAAONT Technical Memorandum Wastewater Treatment Plant Considerations Update Piedmont Lithium Carolinas, Inc. Gaston County, North Carolina February 22, 2022 Page intentionally left blank. Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Contents Contents Contents ......................................................................................................................................i Introduction................................................................................................................................ 1 Projected PLCI Wastewater Characteristics............................................................................... 2 TotalWastewater Flow........................................................................................................... 2 Total Wastewater Flow and Characteristics............................................................................ 3 Potential Impact of PLCI Wastewater on WWTPs...................................................................... 5 PermittedFlows...................................................................................................................... 5 NC Water Quality Standards .................................................................................................. 5 Effluent Characteristics........................................................................................................... 6 Considerations for Long Creek WWTP................................................................................... 8 Conclusion and Recommendations............................................................................................ 9 Tables Table 1. Projected Flows from PLCI Facilities*........................................................................... 3 Table3. Existing Plant Flows..................................................................................................... 5 Table 4. Evaluation of Impact of PLCI water on Long Creek WWTP effluent.............................. 7 i Page intentionally left blank. Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Introduction Introduction Piedmont Lithium Carolinas, Inc. (PLCI) is proposing to construct an open pit mine in the Carolina Tin-Spodumene Belt (TSB) of North Carolina where lithium-bearing pegmatites have been identified. The PLCI Carolina Lithium Project consists of the Concentrate Operations and the Lithium Hydroxide Conversion Plant (the Site) and is located in the TSB of the Piedmont physiographic province in south-central North Carolina. The Site is approximately 1,548 acres in size and is in an unincorporated area of Gaston County on private land surrounding portions of Hephzibah Church Road, Whitesides Road, and St. Mark's Church Road, approximately 1 mile east of Cherryville, North Carolina. The overall Concentrate Operation is composed of three components: the Piedmont Lithium Carolinas Mine #1, a Concentrate Plant, and an Industrial Minerals Plant. The Piedmont Lithium Carolinas Mine #1 will consist of four open pits of varying sizes, a waste rock disposal area, topsoil stockpiles areas, haul roads, and other mine support areas. This process will produce native overburden and dry-stacked concentrator tails at the Concentrate Plant. PLCI is proposing to dry-stack the co-mingled mine refuse streams (native overburden and concentrator tails) in the waste rock disposal area and/or use the refuse for reclamation to backfill the mine pits. The Lithium Hydroxide Conversion Plant will accept concentrated ore from the Concentrate Plant and ultimately produce Analcime tailings, which PLCI is also proposing to dry-stack and co-mingle as mine refuse in the waste rock disposal area. Tailings from either the Concentrate Operation or Lithium Hydroxide Conversion Plant will be mechanically dewatered and dry stacked; slurry impoundments are not proposed. This integrated approach (Concentrate Operations and Lithium Hydroxide Conversion Plant)will allow PLCI to concentrate and convert mined ore to battery- grade lithium hydroxide within Gaston County, Cleveland County, and surrounding areas. HDR Engineering Inc. of the Carolinas (HDR) has been tasked with developing an understanding of potential receiving municipal wastewater treatment plants (WWTPs) that could accept industrial wastewater discharged from the PLCI chemical conversion process. In order to evaluate the potential capability of WWTPs to accept the PLCI process water discharge, National Pollutant Discharge Elimination System (NPDES) permit discharge criteria and the size of receiving streams were evaluated against wastewater characterization parameters developed by HDR based on production information provided by Primero.' NPDES permit discharge criteria are based on the North Carolina 15A NCAC 02B Water Quality Standards for Surface Water and In-Stream Target Values for Surface Waters.2 Four options were identified for possible treatment of the PLCI discharge: the City of Cherryville's Cherryville WWTP, the City of Gastonia's Long Creek WWTP, the City of Shelby's First Broad River WWTP, and the City of Lincolnton's Lincolnton WWTP (Figure 1). The Cherryville WWPT is the closest facility to the PLCI site and was initially considered as the best option due to proximity; however as discussed herein, the three alternative plants all have larger 18605-MEM-PR-009 C, Primero,dated June 14,2021 2 https://deq.nc.gov/documents/nc-stdstable-06102019 1 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations FR treatment facilities and larger receiving streams. In addition, the larger municipalities have active industrial pretreatment programs. LEGEND Q PLCI Carolina Lithium Project l Wastewater Treatment Plants 0 ,-'k Wes 1). R Lin: d n th n C°QF Cherryville WWTP (City of Cherryville) Lincolnton WWTP L+,n]a tr �- - _ _ "'9`� (City of Lincolnton) GASTr,,;, Wigh Shaalr. _ Ch-rrydili- .. K c V tie Long Creek WWTP (City of Gastonia) t Besse m-r m y First Broad River WWTP (City of Shelby) Gastonia P.1 uiilain Etlm5n1 t•rrui-i' � i nl Figure 1. Location of reviewed municipal wastewater treatment facilities Projected PLCI Wastewater Characteristics Total Wastewater Flow The PLCI total facility discharge, based on updated design data provided by Primero on February 16, 2022, is projected to be an average of 0.284 mgd or 197 gpm (Table 1), on which calculations for Tables 2-4 are based. The peak hydraulic design loading for the conveyance system should safely accommodate a greater flowrate than this. The majority of the flow comes from the Lithium Hydroxide Conversion Plant. This plant chemically converts the concentrated lithium from the ore into lithium hydroxide. A smaller stream of wastewater is also generated from the Concentrator Plant. The Concentrator separates the lithium from the rest of the rock present, through grinding and flotation. Sanitary wastewater is combined with process wastewater at the site boundary for proposed disposal to a municipal WWTP. Sanitary wastewater generation rates were calculated using NC standards for wastewater production from manufacturing facilities with showers, at a peak manpower loading of 200 people onsite. 2 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Projected PLCI Wastewater Characteristics Table 1. Projected Flows from PLCI Facilities* Total Wastewater Flow Nominal Average Peak Flow m3/hr** gpm mgd m3/hr** gpm mgd Concentrator Wastewater 7.74 34.1 0.049 15.48 68.2 0.098 Conversion Wastewater 18.6 81.9 0.118 28.1 123.7 0.178 Sanitary Wastewater 0.9 4.0 0.006 1.2 5.3 0.008 Total 27 120 0.173 45 197 0.284 'Due to ongoing refinement in process engineering of facility,flows have changed from previous projections **derived from Primero design data, provided February 16,2022 ^calculated using NC standards for wastewater production from manufacturing facilities with showers, increased to 40 gpd from design standard of 35 gpd for safety Total Wastewater Flow and Characteristics In the Concentrator plant, there are a number of operations in which ores are processed to separate byproducts and undesirable components through gravity and flotation processes. The water recycled in the various operations passes through a clarifier dedicated to that circuit before reuse. Thus, all the water discharged from the concentrator plant is in essence clarified water. The excess water discharged from the concentrator area is treated in a wastewater treatment system consisting of the processes of lime addition for precipitation of fluoride and metals, followed by dissolved air flotation (DAF), sand filtration and granular activated carbon filtration. This process has been projected by Primero to remove fluoride to a concentration of 50 mg/L and TOC to a concentration of 19 mg/L. Other parameters, for which data is not yet available, are estimated based on published solubility data and past observations of coprecipitation of various metals with iron hydroxide precipitates. As shown in Table 2, the raw wastewater iron concentration is 569 mg/L, so the solids produced from increasing the pH will be over 1000 mg/L of iron hydroxide. Due to the projected low TOC concentration after precipitation and activated carbon absorption, it is expected that there will be little remaining MBAS, and foaming issues which previously were identified as a potential concern are no longer expected to be an issue. This wastewater is then blended with the discharge from the Conversion plant. The Conversion plant (also referred to as the lithium hydroxide plant) discharge is made up of the boiler blowdown, the ion exchange elutriant (rinsewater), and bleed streams from filter cake washing, filter cake filtrate and the CO2 scrubber recirculating streams. These streams are not treated other than the treatment received in recirculation. The expected individual stream characteristics and the combination of the concentrator plant and conversion plant waters are shown below in Table 2. Note that there are no other wastewater streams produced onsite. All Cooling Tower and Boiler blowdown streams and solution bleed streams are included in the calculated flows in Table 1 and the characteristics in Table 2. Table 2 also includes the sanitary wastewater stream from all locations on the plant site, using typical sanitary wastewater characteristics for strong sewage. As shown, the combined stream has an average flow of 27.2 cubic meters/hour, or 0.173 mgd. Peak flow is projected to be 0.284 mgd. The principal inorganic constituents include sodium and chloride, with lesser amounts of calcium, sulfate, phosphorus and lithium. 3 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Projected PLCI Wastewater Characteristics Table 2:Wastewater Characteristics Concentrator Conversion Plant Sanitary Design Average Wastewater Wastewater Wastewater Wastewater To TRU nominal high low end high end WTP Calc WTP low end of highend low end end of low end of range high end of range Name Feed Discharge range of range nom of range range design of range conc. of range conc. Flow-Maximum-mgd 0.098 0.178 0.008 0.284 Flow Design-mgd 0.049 0.118 0.006 0.173 Units-Wastewater Parameters mg/L mg/L mg/L mg/L mg/L mg/L mg/L mg/L lb/day mg/L lb/day mg/L Total Dissolved Solids 6170 3072 1536 4609 11131.52 5566 16697 622 6057 4208 16795 11668 Fluoride 2590 50 25 75 1 10 7 31 21 Chloride 250 250 125 375 3845 1923 5768 80 1944 1351 5826 4047 PO4-P 84 17 8.5 25.5 581 290 871 15 289 201 867 602 Carbon(total) 300 300 14 10 14 10 Total Organic Carbon 190 19 1 9.5 28.5 1 250 16 11 24 16 Hardness[mg/Las CaCO3] 1610 2292 1146 3438 125 475 330 1412 981 Aluminum(total) 533 20 10 30 0.1 4.1 2.8 12.3 8.5 Arsenic(total) 0.45 0.30 0.15 0.45 0.00 0.06 0.04 0.18 0.13 Ba ri u m(tota 1) 1.83 1.83 0.92 2.75 0.01 0.37 0.26 1.12 0.78 Be ryl I i u m(tota 1) 0.322 0.100 0.050 0.150 0.001 0.020 0.014 0.061 0.043 Ca I ci u m(tota 1) 568 800 400 1200 10 1 25 50 167 116 518 360 Chromium(total) 5.71 0.10 0.05 0.15 0.01 0.021 0.015 0.062 0.043 Copper(tota 1) 1.32 0.10 0.05 0.15 0.10 0.025 0.018 0.066 0.046 Iron(total) 569 10 5 15 1 2.1 1.5 6.2 4.3 Potassium(total) 33.9 33.9 17.0 50.9 300 100 500 10 106 73 513 356 Lithium(total) 2.41 2.41 1.21 3.62 158 100 207 0.01 99 69 205 142 Magnesium(total) 54.5 54.5 27.3 81.8 10 12 8 34 24 Manganese(total) 91.1 70 35 105 0.1 14 10 43 30 Sodium(total) 461 461 231 692 5988 2994 7385 80 3041 2112 7545 5242 Lead(total) 1.90 0.20 0.10 0.30 0.01 0.04 0.03 0.12 0.09 Anti mony(tota 1) 0.082 0.025 0.013 0.038 0.001 0.005 0.004 0.015 0.011 Selenium(total) 0.0011 0.0011 0.0006 0.0017 0.0030 0.0004 0.0003 0.0008 0.0006 Silicon(total) 392 100 50 150 5 21 14 62 43 Sulfate# 1200 1200 600 1800 250 100 400 70 347 241 1133 787 Thallium(total) 0.0111 0.0020 0.0010 0.0030 0.0010 0.0005 0.0003 0.0013 0.0009 Zinc(total) 7.87 1.00 0.50 1.50 1 0.10 0.21 0.15 0.62 0.43 The projections on water quality are based on chemical consumption and mass balance calculations, and information supplied by process technology and equipment suppliers. Using this information and past experience with treatment of these streams, projected effluent quality from the concentrator treatment system was developed. Laboratory process simulations are in progress to better define the wastewater characteristics for the Concentrator wastewater after treatment and will provide a clearer definition of water quality and blowdown flows. Similarly, for the Converter (lithium hydroxide) plant, process design is still in progress, and some refinement of the characteristics of water from that system is expected. Conservative estimates have been used, so that as more information becomes available, it is expected that the projected discharge water quality will fall within the projected range. 4 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Potential Impact of PLCI Wastewater on WWTPs Potential Impact of PLCI Wastewater on WWTPs Permitted Flows Table 3, below, shows the current and permitted flows to each of the wastewater treatment plants considered, along with the estimated low flow in the receiving stream. Of the WWTPs considered, the Long Creek WWTP has the highest permitted flow capacity, approximately 10 million gallons per day (mgd) more than the next highest flow capacity. Table 2 (below) ranks the WWTPs in order of highest permitted flow capacity to least. The higher the flow capacity, the more advantage a WWTP would have for dilution of the influent wastewater. Table 2 also summarizes the receiving stream minimum flowrates used for NPDES permit limits. The Long Creek and First Broad River WWTPs have substantially more dilution capability as their receiving stream flow is larger and would dilute the WWTP effluent to a greater degree, potentially allowing higher concentrations for some parameters in the effluent discharges (like sulfate and chloride). Allowable parameter effluent levels are determined by the state modelling the receiving streams' mixing zone, to ensure enough dilution of a certain discharge parameter can occur relative to NC stream standards within a short distance of the discharge point. Table 2. Existing Plant Flows Flow(mgd) Instream Low Flow* Rank Facility Current Current Average+ Current Concen-Waste Receiving Stream Permit Average PLCI Peak Maximum (cfs) (mgd) tration* South Fork Catawba River 1 Long Creek WWTP 16 6.2 6.484 27.2 8% 130 84 -Class WS-V First Broad River 2 First Broad River WWTP 6 3.24 3.524 11.8 10% 55 36 -Class C South Fork Catawba River 3 Lincolnton WWTP 3.5 1.96 2.244 12.75 4.16% 83 54 -Class WS-IV Indian Creek 4 Chenyville WWTP 2 0.65 0.934 1.5 16% 9 5.8 -Class C *Current average plus PLCI Peak flow divided by Receiving Stream low flow Evaluation of the Cherryville WWTP indicates that the maximum flow from PLCI would make up about 40% of the average flow to the treatment plant. Given the projected concentration of chlorides and sulfates in the PLCI discharge, Cherryville could not meet the receiving stream water quality criteria for these parameters if the PLCI discharge is directed there. The dilution available in Indian Creek is limited and requires that the Cherryville WWTP discharge be close to the stream water quality standards. Therefore, the Cherryville WWTP is removed from consideration. Based on dilution potential under low flow conditions of receiving streams, particularly for chlorides in this case, it is highly desirable to convey the PLCI wastewater effluent to the Long Creek WWTP and undesirable to convey the PLCI water to the Cherryville WWTP. NC Water Quality Standards All surface waters in North Carolina are assigned a primary classification by the NC Division of Water Resources (DWR). All waters must at least meet the standards for Class C (fishable and 5 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Potential Impact of PLCI Wastewater on WWTPs swimmable)waters. The other primary classifications provide additional levels of protection for primary water contact recreation (Class B) and drinking water (Water Supply [WS] Classes I through V). The state of North Carolina has established water quality standards for surface waters and in-stream target value standards.3 These stream standards define the required quality in the stream, and a WWTP's receiving stream must meet them for its assigned surface water classification, as approved in a WWTP effluent NPDES permit limits. • Class C Waters— is the base waters classification for basic protection of aquatic life and secondary recreation (i.e. fishable and swimmable waters); all waters must at least meet the standards for Class C Waters; • Class WS-IV Waters—water supply waters used as sources for drinking, culinary, or food processing purposes where a WS-1, 11 or III classification is not feasible; usually in moderately to highly developed watersheds; • Class WS-V Waters —water supply waters which are generally upstream and draining to Class WS-IV waters or waters used by industry to supply their employees with drinking water or as waters formerly used as water. The criteria of concern for receiving streams classified as Class WS I-V receiving the PLCI discharge would include Chloride (230 mg/L), Sulfate (250 mg/L), Methylene Blue Active Substances (MBAS) (0.5 mg/L), Arsenic (10 pg/L), Benzene (1.10 pg/L), and polynuclear aromatic hydrocarbons (PAHs) (2.8 qg/L). In comparison, Class C receiving waters have required water quality for the following criteria: Arsenic (150 pg/L) and Chloride (230 mg/L). Class C waters are more heavily monitored for metals. The MBAS test measures the presence of anionic surfactants or detergents to monitor the potential for foaming. In the biological process employed at all four of the plants noted above, foaming in the biological system could: (1) be damaging to the treatment process, as foam formation would limit oxygen transfer; (2) limit the WWTP's ability to separate solids from liquid by stabilizing small particles; and, (3) present operational issues that could result in the WWTP not accepting the influent. The concern is that frothing agents used in flotation would continue to froth once they reach the WWTP. While it is possible that any of these WWTPs could require a stipulation in a pretreatment permit about frothing characteristics, the effluent from the concentrator plant treatment system after passing through solids precipitation and activated carbon would not be expected to contain a substantial concentration of MBAS that would cause foaming to occur. Effluent Characteristics An evaluation was made of the potential impact of the PLCI wastewater on the effluent from the Long Creek treatment plant (Table 3). Table 4 shows characteristics based on the low value and high value of the expected range of possible parameter concentrations. Whereas Table 2 is based on the design values, Table 4 shows a low end of the range that is generally about 50% 3 https://deq.nc.gov/about/divisions/water-resources/planning/classification-standards/surface-water-standards 6 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Potential Impact of PLCI Wastewater on WWTPs less than the nominal value, and a high end that is in most cases 50% above the nominal value. This range reflects (1) the level of accuracy of the design values at this stage of development, and (2) some conservatism in the water quality characteristics to provide a factor of safety. The high flow capacity at the Long Creek WWTP provides substantial dilution, and the receiving stream also provides more dilution than the First Broad River and Lincolnton WWTPs. For the Long Creek WWTP, the projected effluent sulfate, chloride and TDS concentrations are sufficiently low and would meet stream standards in the effluent before considering dilution in the receiving stream. Other parameter concentrations are within or reasonably close to stream standard values. Thus, the best fit for the PLCI wastewater is the Long Creek WWTP. Table 3. Evaluation of Impact of PLCI water on Long Creek WWTP effluent Stream Parameter Units Standards ong Creek PLCI low PLCI high Long Creek Long Creek existing end of end of +low end +high end Discharge effluent range range PLCI PLCI Limits Flow m d 6.2 0.173 0.284 6.373 6.48 16 BOD5 mg/L 3 2 20 3 3.0 5/10 Ammonia N mg/L 0.20 0.10 5.00 0.20 0.25 2/4 Total N m /L 21.1 0.2 10.00 21 22 Sulfate mg/L 250 66 241 787 71 98 Chloride mg/L 250 56 1351 4047 91 231 TDS m /L 1000 223 4205 11668 331 724 PO4-P 2 199 602 7.3 28 Sodium 45 2112 5242 102 273 Calcium 25 116 360 27.7 39.9 Fluoride m /L 1.8 1.0 7.1 21.3 1.2 1.9 Lithium mg/L 0.20 68.62 142.4 2.1 6.4 Arsenic m /L 0.01 0.005 0.043 0.128 0.006 0.010 Benzene* mg/L 0.0011 <0.001 <0.001 <0.001 <0.001 <0.001 PAH m /L 0.0000028 <0.0001 <0.0001 <0.0001 <0.0001 <0.0001 Aluminum mg/L 0.010 2.8 8.5 0.09 0.38 Iron m /L 0.1 1.5 4.3 0.14 0.28 blue is after treatment in Long Creek Treatment Plant red is assumed values based on typical wastewater characteristics The First Broad River WWTP would be a second choice and is also the furthest from the Site. Combined with PLCI effluent, the First Broad River WWTP TDS concentration would be two times the predicted level in the Long Creek WWTP. However, since the First Broad River is Class C, there is no stream standard for TDS. In communication with the City of Shelby, staff indicated that the nearest connection point in Shelby's collection system would need to be upgraded to accept the flow from PLCI. Finally, the Lincolnton WWTP may not be a desirable choice, because the smaller WWTP with the PLCI effluent would have the highest concentrations of sulfate, chloride and TDS. Also, the 7 Piedmont Lithium Carolians,Inc. i Wastewater Treatment Plant Considerations �� Potential Impact of PLCI Wastewater on WWTPs Lincolnton WWTP was originally a 6 mgd facility that was downgraded by the NC Department of Environmental Quality to 3.5 mgd. This downgrade was due to condition of assets within the WWTP and could indicate a potential infrastructure issue. Considerations for Long Creek WWTP The Long Creek WWTP appears to be the best option for the PLCI wastewater; however, based on the information supplied by the facility process engineer, the following parameters still need to be considered and may become discussion points for a pre-treatment permit: Phosphorus, Benzene, PAHs, Fluoride, Lithium, and MBAS. In addition, Gastonia will also evaluate any impacts on biosolids utilization under pretreatment regulations. Phosphorus (particularly phosphate) is a nutrient that is frequently the controlling factor in biological growth and is commonly controlled to prevent undesirable levels of biological activity in streams. Evaluations are currently in progress to make changes to the production process to eliminate most of the phosphorus present. Benzene is a component of kerosene, which is used in limited amounts at the Concentrator plant. It is largely biodegradable and should be effectively removed in the WWTP biological treatment process; however, the current characterization does not yet include data for benzene. Benzene is also effectively removed by activated carbon and would not be expected to be present in the effluent from the Concentrator Treatment System. Polynuclear Aromatic Hydrocarbons (PAHs) can also be present in kerosene and are not generally well biodegraded. However, PAHs are also effectively removed by activated carbon, and should thus be limited in the discharge from the facility, if further characterization work indicates that PAH concentrations in the wastewater are problematic, pretreatment for PAH removal may be required. It is not expected that either Fluoride or Lithium would negatively impact the South Fork Catawba River at the concentrations shown in Table 4. MBAS is a concern because the frothing agents used in flotation would continue to froth once they reach the WWTP, so the potential exists for a foaming issue. However, MBAS (being organic compounds) also have a tendency to be absorbed onto activated carbon and should thus be very limited in the Concentrator Treatment System. Additionally, the anticipated increase in sulfate, chloride and TDS concentrations could have an impact on the Long Creek WWTP's effluent toxicity testing. However, only bench scale testwork or actual testing would accurately determine this. Bench scale testing could be conducted on a mixture of actual municipal wastewater from the Long Creek WWTP and a synthetic solution of PLCI wastewater once the PLCI stream is better characterized. It would be ideal for the mixture to be subject to the same treatment processes employed at the Long Creek WWTP, which may be difficult. A literature-based evaluation of potential toxicity issues for a municipal wastewater and PLCI wastewater mixture is likely effective in lieu of actual treatment per Long Creek WWTP processes. It is recommended to pursue connection to Gastonia based on: 8 Piedmont Lithium Carolians,Inc. I Wastewater Treatment Plant Considerations �� Conclusion and Recommendations • The Long Creek WWTP has a pretreatment program; • the capacity at Gastonia's Long Creek WWTP is best able to accept the waste stream of the WWTPs evaluated; and • the receiving stream (South Fork Catawba River) has the largest flow of all receiving streams associated with the evaluated WWTPs. There are two potential connection points to Gastonia's collection system for initial consideration — one at the Apple Creek Business Industrial Park and one at the High Shoals Lift Station near Gaston County Landfill (upstream of the Long Creek WWTP). The next steps would be to continue discussions with Gastonia on connection points, determine alternatives for the infrastructure needed to convey the waste to the connection point, and then implementation (design, permitting, construction). Conclusion and Recommendations In conclusion, the best WWTP option to discharge PLCI's wastewater would ultimately be to the Long Creek WWTP. Not only is the WWTP facility equipped to handle the volume and characteristics of the PLCI wastewater, but the receiving stream also has a flow capacity that will further dilute the wastewater to desirable stream standards. A full wastewater characterization has been requested from the facility engineers and will be done as part of process development work currently in progress. Gaps in PLCI effluent data come largely from activated carbon removal efficiencies for MBAS and organic alcohols, as well as inorganic parameters whose concentration will be controlled by coprecipitation in the fluoride precipitation step of the Concentrator treatment plant. In lieu of a full wastewater characterization, a literature-based review of the impact of the various components of the PLCI water on the treatment process, residual solids characteristics and potential toxicity impacts could be conducted. 9 440 S Church Street, Suite 1200 Charlotte, NC 28202 704-338-6710 hdrinc.com © 2022 HDR, Inc., all rights reserved PIEDAAONT Technical Memorandum Carolina Lithium - Wastewater Characterization Piedmont Lithium Carolinas, Inc. Gaston County, North Carolina November 9, 2022 Page intentionally left blank. Piedmont Lithium Carolians, Inc. I Wastewater Characterization �� Contents Contents Contents ......................................................................................................................................i Introduction................................................................................................................................ 1 TotalWastewater Flow............................................................................................................... 1 Wastewater Stream Characteristics ........................................................................................... 2 Concentrator Plant Wastewater Characteristics...................................................................... 2 Conversion Plant Wastewater Characteristics........................................................................ 3 Mixed Wastewater Characteristics.......................................................................................... 4 Precipitates......................................................................................................................... 5 Metalloids............................................................................................................................ 6 OtherImpacts ..................................................................................................................... 6 Summary ................................................................................................................................... 7 Tables Table 1. Projected Flows from Carolina Lithium Project Facilities .............................................. 2 Table 2. Concentrator Plant Wastewater Sample....................................................................... 3 Table 3. Conversion Plant Wastewater Sample ......................................................................... 4 Table 4. Combined Wastewater Characteristics......................................................................... 5 i Page intentionally left blank. i Piedmont Lithium Carolians,Inc. I Wastewater Characterization �� Introduction Introduction Piedmont Lithium Carolinas, Inc. (Piedmont) is proposing to construct an open pit mine in the Carolina Tin-Spodumene Belt (TSB) of North Carolina where lithium-bearing pegmatites have been identified. The Carolina Lithium Project (the Site) consists of the Concentrate Operations (Concentrator Plant) and the Lithium Hydroxide Conversion Plant (Conversion Plant) and is located in the TSB of the Piedmont physiographic province in south-central North Carolina (NC). The Site is approximately 1,548 acres in size and is in an unincorporated area of Gaston County on private land surrounding portions of Hephzibah Church Road, Whitesides Road, and St. Mark's Church Road, approximately 1 mile east of Cherryville, North Carolina. The production of lithium from the lithium-bearing pegmatites called spodumene, requires production of a spodumene concentrate and conversion to lithium hydroxide. In the Concentrate Operations process, grinding and flotation are used to separate the undesirable components from spodumene, resulting in an increased concentration of lithium in the spodumene concentrate product. Some of these processes are wet and involve the use of chemical reagents to enhance separation. The spodumene concentrate is then taken to the Conversion Plant, where it is then chemically converted to lithium hydroxide. Both of these operations use water and generate wastewater streams that would require treatment prior to discharge. This integrated approach (Concentrate Operations and Lithium Hydroxide Conversion Plant) will allow Piedmont to concentrate and convert mined lithium-bearing spodumene to battery-grade lithium hydroxide. Piedmont intends to pretreat the collected onsite process wastewater to discharge to Two Rivers Utilities (TRU) for treatment at their Long Creek Wastewater Treatment Plant (WWTP). In order to evaluate the potential quality of generated wastewater, Piedmont in conjunction with Primero and Metso-Outotec, simulated the concentration and conversion processes in a laboratory, utilizing ore samples extracted from the site. The laboratory simulation employed the proposed processes that will be used to produce the spodumene concentrate which is then used to produce battery-grade lithium hydroxide as the final product. The laboratory simulation was conducted by North Carolina State University for the concentrator process and by Metso- Outotec for the conversion process. HDR Engineering Inc. of the Carolinas (HDR) was tasked with ordering the laboratory analysis and analyzing the characterization results of the two separate wastewater streams from each of the Concentrate and Conversion Plants. To characterize and analyze the combined discharge as one wastewater stream, HDR simulated the combined discharge mixture using OLI Flowsheet (version 10.2), which is a software used to model process chemistry in chemical process and treatment systems. This technical memo outlines and identifies the wastewater characteristics of the separate wastewater streams as well as the combined mixture. Total Wastewater Flow The Carolina Lithium Project total facility discharge is expected to consist of combined wastewater from the Concentrator Plant, the Conversion Plant, and sanitary wastewater 1 Piedmont Lithium Carolians,Inc. I Wastewater Characterization �� Wastewater Stream Characteristics generated onsite. The Concentrate and Conversion Plant wastewaters will be pretreated as needed to comply with TRU provided requirements, while the sanitary wastewater will be conveyed along with the pretreated wastewater to the Long Creek WWTP. The projected flowrates from the Carolina Lithium Project facilities are summarized in Table 1. The peak hydraulic design loading for the conveyance system should safely accommodate a greater flowrate than the indicated peak. The majority of flow comes from the Lithium Hydroxide Conversion Plant. This plant chemically converts the lithium-bearing spodumene concentrate to lithium hydroxide. A smaller wastewater flow is generated from the Concentrator Plant. Sanitary wastewater is combined with process wastewater at the site boundary for proposed disposal to the Long Creek WWTP. Sanitary wastewater generation rates were calculated using NC standards for wastewater production from manufacturing facilities with showers, at a peak manpower loading of 200 people onsite. Table 1. Projected Flows from Carolina Lithium Project Facilities Total Wastewater Flow Nominal Average Peak Flow m3/hr* gpm mgd m3/hr* gpm mgd Concentrator Wastewater 7.74 34.1 0.049 15.48 68.2 0.098 Conversion Wastewater 18.6 81.9 0.118 28.1 123.7 0.178 Sanitary Wastewater** 0.9 4.0 0.006 1.2 5.3 0.008 Total 27 120 0.173 1 45 197 0.284 "derived from Primero design data, provided February 16,2022 calculated using NC standards for wastewater production from manufacturing facilities with showers,increased to 40 gpd from design standard of 35 gpd for safety Wastewater Stream Characteristics Concentrator Plant Wastewater Characteristics The primary process of the Concentrator Plant is to separate lithium-bearing spodumene from the byproducts and undesirable components through gravity and flotation processes. Water used in this facility is recycled extensively. A laboratory simulation of the Concentrate Operations produced a sample of wastewater, representative of the blowdown stream from the Concentrator Plant without pretreatment, which was then analyzed by Pace Laboratories, a certified North Carolina laboratory. The analytical results from this sample are summarized in Table 2. There was a limited sample amount generated from the Concentrate Operations simulation; as such, the analytical identification is limited to parameters which were suspected to be present by virtue of their use in production operations or in the raw material. Notable results from this analysis include a pH of 2.0, aluminum concentration of 363 mg/L, fluoride concentration of 272 mg/L, and silicon concentration of 656 mg/L. 2 Piedmont Lithium Carolians,Inc. I Wastewater Characterization �� Wastewater Stream Characteristics Table 2. Concentrator Plant Wastewater Sample Parameter Units Result Iron mg/L 78.6 Manganese mg/L 11.9 Potassium mg/L I 38.3 Sodium mg/L 518 Calcium mg/L 141 Magnesium mg/L 24.9 Silicon mg/L 656 Aluminum mg/L 363 Beryllium mg/L 0.097 Chromium mg/L 1.41 Copper mg/L 0.060 Lead mg/L 0.198 Molybdenum mg/L 0.121 Nickel mg/L 0.925 Zinc mg/L 1.79 Lithium mg/L 2.25 Total Dissolved Solids (TDS) mg/L 4700 pH Std 2.0 Total Kjeldahl N mg/L 11.2 Fluoride mg/L 272 Phosphorus mg/L 9.3 Chemical Oxygen Demand mg/L 4050 Total Organic Carbon (TOC) mg/L 222 Conversion Plant Wastewater Characteristics The Conversion Plant (also referred to as the Lithium Hydroxide Conversion Plant) discharge is comprised of the boiler blowdown, the ion exchange elutriant (rinsewater), and bleed streams from filter cake washing, filter cake filtrate and the CO2 scrubber recirculating streams. The sample generated in the laboratory simulation is representative of the sum of these streams, without pretreatment. The analysis of sample that simulates the production of this wastewater stream is shown below in Table 3, which was also analyzed by Pace Laboratories, a certified North Carolina laboratory. Notable characteristics of the simulated Conversion Plant wastewater include substantial concentrations of sodium, chloride and phosphorus. 3 Piedmont Lithium Carolians, Inc. I Wastewater Characterization Wastewater Stream Characteristics Table 3. Conversion Plant Wastewater Sample Parameter Units Result Potassium mg/L 272 Arsenic mg/L 0.239 Aluminum mg/L 1.25 Antimony mg/L 0.105 Selenium mg/L 0.328 Sodium mg/L 11,400 Silicon mg/L 98 Lithium mg/L 137 pH Std units 10.3 Chloride mg/L 3560 Phosphorus mg/L 1250 COD mg/L 164 TKN mg/L 0.76 Note that there are no other process wastewater streams produced onsite. Cooling tower and boiler blowdown streams and solution bleed streams are included in the projected flows in Table 1 and the characteristics in Table 2 and Table 3. Mixed Wastewater Characteristics In order to evaluate the chemistry of the combined wastewaters from both the Concentrator and Conversion Plants, a model was prepared in the OLI Flowsheet (version 10.2) software. Graphically the model is as shown below. 10. Concentrator Mixed 10 Wastewater Conversion Plant Mix-1 The software models the chemistry of the two wastewater streams, and identifies the precipitation of solids, mixture pH, and overall combined wastewater characteristics. For this model, average flowrates were used and the inputs were the two sets of characteristics presented in Table 2 and Table 3. The output for this model given the inputs in Table 2 and Table 3, is shown in Table 4. The columns marked liquid indicate soluble components of the wastewater. The columns labelled as solids are precipitated and are present in the liquid as suspended or colloidal solids. Sanitary wastewater was not included in this model, as the flow is low and the presence of the contaminants from production operations is minimal. 4 Piedmont Lithium Carolians,Inc. I Wastewater Characterization �� Wastewater Stream Characteristics Table 4. Combined Wastewater Characteristics Concentrator Plant Conversion Plant Combined Wastewater Parameter Liquid Solids Total Liquid Solids Total Liquid Solids Total mg/L mg/L Ib/hr mg/L mg/L Ib/hr mg/L mg/L Ib/hr Si(+4) 53 600 11.2 97 4 52 190 15.1 Na(+1) 515 0 9.0 11277 449 7999 458 CI(-1) 0 0 0.0 3533 141 2449 140 K(+1) 38 0 0.7 269 10.7 199 11.4 AI(+3) 361 0 6.3 0.49 0.76 0.050 10.4 101 6.4 F(A) 271 0 4.7 79 4.0 4.7 Ca(+2) 141 0 2.4 0.2 42.7 2.4 Fe(+3) 62 16.2 1.4 0.000007 23.8 1.36 Mg(+2) 24.8 0 0.43 7.6 0.43 Mn(+2) 11.9 0 0.21 3.10 0.54 0.21 P(+5) 0.220 9.0 0.13 1236 49.3 829 33.2 49.4 Li(+1) 2.2 0 0.039 136 5.41 95 5.4 Zn(+2) 1.8 0 0.032 0.2880 0.266 0.0318 Cr(+3) 1.4 0 0.024 0.0010 0.423 0.0243 Ni(+2) 0.93 0 0.016 0.2830 0.000 0.0162 Pb(+2) 0.19 0 0.0034 0.0047 0.054 0.0034 Cu(+1) 2.23E-06 0.070 0.0012 1.0E-07 0.021 0.0012 Mo(+6) 0.121 0.000 0.0021 0.0310 0.006 0.0021 Be(+2) 0.093 0.000 0.0016 0.0282 0 0.0016 As 0.24 0.010 0.17 0.01 Sb 0.11 0.004 0.07 0.00 Se 0.33 0.013 0.23 0.01 TOC 222 3.8 0.00 65.5 3.80 COD 4040 69.1 164 6.7 1307 75.79 TKN 11.2 0.2 0.76 0.031 3.84 0.22 Flow, gpm 34.2 81.8 116 pH, std 2 10.3 6.3 units Review of Table 4 leads to several observations related to the characteristics of the modeled combined wastewater. Precipitates • First, when mixed in the proportions generated, the two wastewater streams function to neutralize each other, with a resulting pH of 6.3. • Precipitates are formed in the mixture as might be expected at a near-neutral pH. The largest concentration comes from silicon in the Concentrator Plant wastewater. At ambient conditions, silica (Si02) is only soluble to about 100 to 150 mg/L; silica solubility increases substantially at an approximate pH of 9 or higher. Since the silica was present mostly in the Concentrator Plant wastewater at acidic pH levels, even though the silica 5 Piedmont Lithium Carolians,Inc. i Wastewater Characterization �� Wastewater Stream Characteristics was input as soluble silica, the model correctly identified that if it was soluble as an input, it quickly precipitated. It is likely that most of the silica is present as fine or colloidal sand. • Aluminum is the next highest concentration of precipitate in the combined wastewater. The minimum solubility of aluminum hydroxide occurs at a pH of 6 to 6.5. The model indicates that the mixture will have approximately 10 mg/L soluble aluminum and about 100 mg/L aluminum present as aluminum hydroxide and possibly other precipitates. Aluminum hydroxide is soluble to only tenths of a mg/L at this pH. The model indicates that AIF3 and AIFa' are both present in solution in the range of 15 to 20 mg/L as soluble complexes and thus maintains the aluminum in solution. As the combined wastewater is diluted in domestic wastewater, the dilution of these complexes will allow for precipitation of aluminum hydroxide to produce low soluble aluminum concentrations. • Nearly all of the calcium and iron in the combined wastewater are precipitated. The OLI model indicates these are in the form Ca5(PO4)3F and FeP042H2O. Concentrations of under 1 mg/L are precipitated of manganese, zinc, chromium, lead, copper and molybdenum, as phosphates, oxides and hydroxides. Metalloids • In Table 4, below the metals analyses are a block of metalloids and conventional parameters. The OLI model requires speciation data to accurately predict the reactions involving metalloids, which was not available due to limitations in the volume of sample generated. These parameters and the conventional parameters are included purely on the basis of mass balance with no accounting for reactions that might capture them as solids. It is likely that some of the arsenic and antimony will co-precipitate with iron and aluminum precipitates. The degree of removal of arsenic, antimony, iron, and aluminum, and the removal of any selenium by coprecipitation, is a function of pH and redox-driven speciation of the metalloid. The concentrations shown as soluble in the combined wastewater are thus the worst-case modeled condition. Other Impacts • Removal of the precipitated solids by clarification or filtration would result in the removal of most of the precipitates in the combined wastewater. • For conventional parameters, the Concentrator Plant wastewater COD is an order of magnitude higher than the associated TOC. This may be due to the demand for oxygen from the metals being oxidized in the COD test. It would normally be expected that in the absence of large concentrations of ammonia nitrogen (a component of TKN which are all relatively low) that oxygen demand would be on the order of 2.7 times the organic carbon. It is believed on this basis that the TOC values offer a better representation of the organic loading coming to the treatment facility. As noted, TKN concentrations are projected to be below 10 mg/L. • Of the soluble components identified in the analysis of the laboratory simulated wastewater samples, the largest soluble components in the combined wastewater include sodium, chloride, and phosphorus. The lithium concentration in the combined wastewater is 95 mg/L, and the soluble fluoride is 79 mg/L. 6 Piedmont Lithium Carolians,Inc. I Wastewater Characterization �� Summary • For the Concentrator Plant wastewater, methylene blue active substance (MBAS) was found to be 0.43 mg/L. TDS was found to be 4700 mg/L. Ammonia was identified at 0.49 mg/L and nitrate/nitrite nitrogen was 0.1 mg/L. Barium was 0.82 mg/L. Thallium was below the reporting limit. Acetone was reported as 0.06 mg/L. • For the Conversion Plant wastewater, MBAS was not run (no surfactants are used there). Total nitrogen was 0.95 mg/L. Traces of chromium and cadmium were present (below 0.1 mg/L), and aniline was identified as below detection limits. Summary Piedmont intends to pretreat the collected onsite process wastewater to the degree necessary to discharge to the TRU Long Creek WWTP. It is Piedmont's understanding that TRU is currently evaluating the capability of the Long Creek WWPT to accept wastewater components such as the ones discussed herein. The modeling of the combined wastewater discharge to include both the Concentrator and Conversion Plant wastewaters does not include onsite pretreatment at this time; however, pending the provision of parameters and criteria from TRU, Piedmont would tailor a pretreatment design to accommodate TRU's requirements. 7 440 S Church Street, Suite 1200 Charlotte, NC 28202 704-338-6710 hdrinc.com © 2022 HDR, Inc., all rights reserved Piedmont Lithium Carolinas,Inc.I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Appendix C — Attachment 2 PLCI Letter to Two Rivers Utilities (April 11 , 2023) Two Rivers Utilities Response (April 26, 2023) Page intentionally left blank. P I E N T LITHIUM April 11, 2023 Via Electronic Mail Ms. Stephanie Scheringer Division Manager Wastewater Treatment Two Rivers Utilities 1300 N. Broad St Gastonia, NC 28054 Re: Piedmont Lithium Inc. Significant Industrial User Permit Dear Ms. Scheringer, Piedmont Lithium Inc. ("Piedmont") and Two Rivers Utilities ("Two Rivers") continue to engage in discussions related to Two Rivers issuing Piedmont a Significant Industrial User ("SIU") permit for process wastewater discharged from Piedmont's Carolina Lithium project in Gaston County, North Carolina. Piedmont and Two Rivers agree and acknowledge that their discussions regarding the Carolina Lithium project are part of Piedmont's broad effort to obtain permits and approvals from other State and local agencies related to the Carolina Lithium project. In an effort to facilitate the above, Piedmont shall meet all SIU permit limits and conditions in compliance with all applicable laws and regulations required by Two Rivers as such limits and conditions relate to Piedmont's sanitary sewer discharge from the Carolina Lithium project. If there are any questions concerning this matter, please contact me at (704) 813-2301 or mparker piedmontlithium.com. Thank you, J. Monique Parker, CSP SVP — Safety, Environment & Health Piedmont Lithium Inc. • .. • Australia Address OX- 4 nfo@piedrnontlithiumcom PIEDMONT Page intentionally left blank. TWO VERS U T I L I T I E S We are TRU to our customers! April 26, 2023 Via Electronic Mail Ms. Monique Parker, CSP Senior Vice President for Safety, Environment and Health Piedmont Lithium Inc. 42 E. Catawba St. Belmont, NC 28012 RE: Acceptance of Wastewater Discharge Dear Ms. Parker: Two Rivers Utilities (TRU) has received Piedmont Lithium's (Piedmont) April 11, 2023 letter regarding wastewater from the planned Carolina Lithium mining and processing operation in Gaston County. It is acknowledged that Piedmont and TRU continue to discuss the makeup of the sanitary sewer discharge and the future Significant Industrial User(SIU) permit that is required for the sanitary sewer discharge from the Carolina Lithium project. Two Rivers Utilities has the available capacity at the Long Creek Wastewater Treatment Plant to treat the proposed volume of wastewater from this project, which is a peak flow of 0.284 MGD for combined domestic and process discharge. Per Piedmont's April 11, 2023 letter stating that all SIU permit limits and conditions, as well as all applicable laws and regulations related to Piedmont's sanitary sewer discharge will be met, TRU can accept and effectively treat the wastewater from the Carolina Lithium project. TRU will continue to work with Piedmont to best determine appropriate limits and conditions for this discharge before construction is completed. However, limits or conditions in Piedmont Lithium's SIU permit may be revised in accordance with the City of Gastonia Code of Ordinances Section 14-289 due to unforeseen or undisclosed pollutants (including, but not limited to the PFAS/PFOA family of compounds), municipal treatment process interference, changing regulations or other conditions. In accordance with Gastonia's Code of Ordinances Section 14-396, 397 and 399, Piedmont will be obligated to meet any change in requirements. Two Rivers Utilities appreciates the information that has been provided thus far and looks forward to continuing to work with Piedmont Lithium through the remainder of the SIU permitting process. Sincerely, Stephanie Scheringer Division Manager Wastewater Treatment Two Rivers Utilities CC: Joe Albright, Director Public Utilities,TRU Brian Potocki,Assistant Director Public Utilities,TRU David Shellenbarger,Assistant WWT Division Manager Compliance,TRU L.Ashley Smith,City Attorney, Gastonia Keyes McGee, Pretreatment Coordinator, NCDEQ DWR Page intentionally left blank. Piedmont Lithium Carolinas, Inc. I Response to DEMLR Additional Information Request Comments on Carolina Lithium Project by DWR-WQPS January 14,2022 Appendix C — Attachment 3 LEAF and Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96) Collaboration Technical Summary Page intentionally left blank. Leaching Environmental Assessment Framework (LEAF) and Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96) Collaboration Technical Summary April 2023 Prepared for: Prepared by: Piedmont Lithium Carolinas, Inc. Marshall Miller &Associates, Inc. 42 East Catawba Street 582 Industrial Park Road Belmont, NC 28012 Bluefield, Virginia 24605 www.mmal.com Page intentionally left blank. Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials 1k, ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary April2023 Table of Contents Page No. 1 Introduction ......................................................................................................................1 2 Leaching Environmental Assessment Framework(LEAF)Testing.........................................2 3 Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96)..............................................................................................................4 4 Summary of Results...........................................................................................................5 5 Operation Plan for Monitoring and Potential Mitigation for Waste Rock Disposal Areas and Backfilled Pits......................................................................................8 5.1 Above-Ground Waste Rock Disposal Area................................................................... 8 5.2 Pit Backfill Waste Rock Disposal Areas......................................................................... 9 Attachments 1 ...................Table of Applicable State and Federal Guidelines for Groundwater and Surface Water 2 ................................................................................................. LEAF Method 1313 Screening Results 3 ....................................................................................Summary of 2019 & 2021-2022 Humidity Cell (ASTM D5744 [reapproved 2001]) Leaching Results 4 ....................................LEAF Test Results RE: V, Al, As and pH under "natural" leachage conditions 5 ............................ Duration of Elevated pH Relative to Regulatory Standards in Humidity Cell Tests 6 ....................................................................................... Humidity Cell Test Results RE: V, Al, and pH 7 ........................................................Summary of Elevated Parameters in Humidity Cell Test Results Exhibits 1 ...............................................................................................Conceptual Reclamation Flow Diagram 2 ........................... Conceptual Diagram of Water Collection and Monitoring System in Backfilled Pit MARSHALL MILLER&ASSoc1ATE5,INc. 1 Page intentionally left blank. Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►►' ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary April2023 1 Introduction In response to North Carolina Division of Energy, Mineral, Land, and Resources' (DEMLR) additional information request item 4, dated January 14, 2022; Piedmont Lithium Carolinas, Inc. (PLCI) is providing the following details with regard to our current reclamation plan associated with placement of waste rock and tailings material in above-ground disposal areas and backfilled mine pits. This document assumes that all tailings and waste rock materials to be exposed of in the proposed above- ground and pit backfill disposal areas will originate from PLCI's North Carolina mine. The waste rock and tailings assessment, upon which the reclamation plan is based, has evolved since the initial submittal of the mine permit application in August 2021. To date, the waste rock and tailings material assessment includes Acid-Base Account (ABA) testing, "whole rock" elemental determination, Toxicity Characteristic Leaching Procedure (TCLP), Leaching Environmental Assessment Framework (LEAF) [LEAF Method 1313], and a kinetic testing program through use of the Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96) protocol. The most current evolution of the assessment includes completion of LEAF testing (as recommended by DEMLR) and additional kinetic (humidity cell) testing; the results of which are now incorporated into the updated reclamation plan. Samples for LEAF test analyses were collected and compiled by PLCI and PLCI coordinated with Eurofins Pittsburgh (Pittsburgh, Pennsylvania) to conduct the LEAF testing. Sample collection for the humidity cell work was completed by PLCI and Marshall Miller&Associates(MM&A), and MM&A coordinated with SGS Laboratory(Lakefield, Ontario,Canada)to conduct the ASTM D 5744- 96 testing. The inclusion of the additional test results into the assessment provides a more thorough understanding of both the short-term and long-term potential leaching characteristics associated with the waste rock and concentrator plant tailings (both with and without by-products associated with feldspar recovery). In this context, the LEAF testing provides an initial screening "snapshot" of potential "worst case" leaching conditions under various hypothetical scenarios and helps to identify Constituents of Potential Concern (COPC). Subsequently, the humidity cell testing (ASTM D 5744-96) provides results that are indicative of more representative (but still potentially aggressive compared to actual field conditions), long-term expected conditions of leaching potential.The humidity cell testing provides a means to more thoroughly evaluate the COPCs identified by the LEAF testing. The LEAF and humidity cell analyses indicate that production of acidic drainage from the waste rock and tailings, initially considered to be a possibility in some cases, is not expected. As discussed in previously submitted information, the waste rock for the site was characterized as either Potentially Acid Generating (PAG) rock or non-Potentially Acid Generating (non-PAG).The distinction between the PAG and non-PAG rock was based on previous ABA testing that indicated that some of the waste rock from the East Pit Extension area (the southeast corner of the East Pit) had the potential to create acidic MARSHALL MILLER&Assocmms,INc. 1 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 conditions. The distinction was originally identified as a change in rock type by PLCI geologists during exploration drilling activities. In general, approximately 93 percent of the waste rock for the entire mine is amphibolite that is non-PAG throughout. The remaining 6-7 percent of the waste rock is a mixture of schist, mudstone, and amphibolite that was initially suspected of containing some PAG material. While initial ABA testing suggested the PAG material had the potential to produce acidic conditions, acidic conditions were not observed in the long-term results from ASTM D 5744-96 (humidity cell) testing. In contrast, the newly-available test data indicate that the waste material (waste rock and concentrator tailings) has the potential to temporarily elevate pH values in the earliest stage of leachate production, with long-term humidity cell testing showing that the elevated pH values are expected to quickly and naturally buffer to a near-neutral pH value. The behaviors of COPCs identified by LEAF and further analyzed via ASTM D 5744-96 (humidity cell testing) are discussed in subsequent sections below. In general, the results of the revised assessment suggest that initial placement of waste material may be expected to result in a "first flush" of water drainage that temporarily exhibits elevated pH values, but that will naturally buffer to a near neutral pH condition. The results of the testing indicate that the temporarily elevated pH leachate can be associated with concentrations of COPCs that, in some cases, may have the potential to temporarily exceed regulatory guidelines for groundwater and/or stream water quality. Long-term ASTM D5744-96 results indicate that, in nearly all cases, elevated pH values and associated COPC concentrations are expected to decrease rapidly as leaching progresses. In consideration of the results of the updated assessment, PLCI has modified the previous reclamation plan. The revised reclamation plan now includes placement of only waste rock and concentrator plant tailings for backfilling of pits and construction of the proposed above-ground waste rock disposal areas. Placement of tailings associated with the conversion plant into above-ground waste rock disposal areas and backfilled pits on the mine site is not part of the current revised plan. The subsequent sections of this document include summary background information for LEAF and ASTM D 5744-96 (humidity cell) testing methodologies; a summary of the results from the LEAF and ASTM D 5744-96 testing;and details of the revised waste disposal and reclamation plan. A table summarizing applicable parameter guidelines for groundwater and surface water is included as Attachment 1. 2 Leaching Environmental Assessment Framework (LEAF) Testing PLCI (via Eurofins) conducted multiple LEAF Method 1313, pH Dependence tests to evaluate "worst case" leaching potential for numerous potential waste material combinations. The material analyzed with LEAF Method 1313 included both waste rock (PAG and non-PAG) and tailings from the proposed concentrator plant. The LEAF testing (recommended by DEMLR) supplemented and confirmed results of other testing (ASTM D 5744-96) conducted by PLCI. The LEAF test results assist with developing management and mitigation measures to minimize and prevent leaching of COPCs. MARSHALL MILLER&Assocmms,INC. 2 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►►' ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 The LEAF testing was completed on representative 1 kilogram (kg) samples, with potential material combinations based on anticipated production rates during normal mining operations. The current assessment considers LEAF testing of the following material combinations: > PAG waste rock > non-PAG waste rock > Concentrator Tailings > PAG/non-PAG waste rock > PAG/non-PAG/Concentrator Tailings > PAG/Concentrator Tailings > non-PAG/Concentrator Tailings Based on input from Eurofins, the LEAF Method 1313 testing was conducted over a pH range from 4.0 — 9.0, and tests under Synthetic Precipitation Leaching Procedure (SPLP) (beginning pH near that of rainwater) and "natural" (de-ionized water) conditions were also completed as part of the LEAF testing program. The LEAF sample material was milled to a size of 2 millimeters or less, which is much smaller than the expected size of waste rock material to be placed under actual conditions. The reduced size, and therefore increased surface area, of the material tested with LEAF methods artificially increases the potential leachability of the material, as compared to expected actual conditions. The LEAF Method 1313 testing provides an initial screening at a wide range of pH values including those that are unrealistic for the project conditions; consequently, LEAF 1313 provides only an initial "snapshot" for COPCs that could be associated with leaching of the waste material. The results from LEAF are generally consistent with the earliest stages of long-term ASTM 5744-96 (humidity cell) test results (further discussion below). The LEAF How-To Guide (May 2019) issued by the United States Environmental Protection Agency (EPA) establishes that the various LEAF methods are not regulatory compliance tests, and should not be used as such. Instead, LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies. Specifically, the LEAF How-to Guide states: "The LEAF tests and approach is voluntary and not a requirement under the Resource Conservation and Recovery Act (RCRA). This guidance provides a general approach that needs to be tailored to the specific application or regulation under which it is being used.....LEAF is not a regulatory test but may be useful in support of evaluations not designed to meet requirements under the RCRA regulations. The use of LEAF on a site-specific basis needs to be tailored to the questions being asked. The usefulness of LEAF testing will depend on how well test results estimate environmental conditions for a specific application." MARSHALL MILLER&ASSOcmms,INc. 3 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 For the current assessment, LEAF Method 1313 testing has been completed on seven samples representative of the site (not including conversion plant tailings). Summary results tables for each of the individual LEAF tests are included in Attachment 2. The tables summarize results of the testing for laboratory-controlled pH ranges from 4.0 to 9.0, for "Natural" conditions, and for SPLP analysis. The results of the LEAF 1313 testing are discussed in detail in the Summary of Results section of this document. 3 Accelerated Weathering of Solid Materials Using a Modified Humidity Cell (ASTM D 5744-96) Humidity Cell Testing is a kinetic test that subjects a material to varying oxidizing and rewetting conditions over time to simulate the changes in drainage quality with changing composition of a material undergoing leaching. The test method involves periodic (often weekly) leaching of a 1-kg sample of solid material with a water of specified purity. In the current case,the testing was completed with de-ionized water. The test is commonly used in the mining industry to evaluate how drainage characteristics from mining waste material may be expected to change over time. Important notes excerpted from the ASTM International [formerly American Society for Testing and Materials (ASTM)] information for humidity cell testing(ASTM D 5744-96)1 are included below to emphasize the relevancy of the test method to the current assessment: "This accelerated weathering test method is designed to increase the geological-chemical- weathering rate for selected 1000-g solid material samples and produce a weekly effluent that can be characterized for solubilized weathering products." "The purpose of this accelerated weathering procedure is to determine the following: (1) whether a solid material will produce an acidic, alkaline, or neutral effluent, (2) whether that effluent will contain diagnostic cations (including trace metals) and anions that represent solubilized weathering products formed during a specific period of time, and (3) the rate at which these diagnostic cations and anions will be released (from the solids in the effluent) under the closely controlled conditions of the test." "The principle of the accelerated weathering test method is to promote more rapid oxidation of solid material constituents than can be accomplished in nature and maximize the loadings of weathering reaction products contained in the resulting weekly effluent." 1 D 5744—96(Reapproved 2001),Standard Test Method for Accelerated Weathering of Solid Materials Using a Modified Humidity Cell,ASTM International. MARSHALL MILLER&ASSOcmms,INc. 4 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 "This test method has been tested on both coal and metal mine wastes to classify their respective tendencies to produce acidic, alkaline, and neutral effluent, and to subsequently measure the concentrations of selected inorganic components leached from the waste." "An assumption used in this test method is that the pH of each of the leachates reflects the progressive interaction of the interstitial water with the buffering capacity of the solid material under specified laboratory conditions." As stated, the humidity cell testing allows for assessment of the effects on the leachate from progressive buffering capacity of the solid material overtime, a factor that is not accounted for by LEAF 1313 testing. The humidity cell testing included introduction of de-ionized water and the waste rock material was reduced to a size much smaller (less than 6.35 mm) than that of the planned waste rock material, both of which factors increase the propensity for leaching to occur. For the current assessment, ASTM D 5744-96 testing has been completed for thirteen (13) samples. Attachment 3 includes individual results summary sheets for the humidity cell tests. 4 Summary of Results As stated above, the results of the recent testing program and revised assessment resulted in modification of the proposed reclamation plan. Specifically, the current plan for on-site material disposal includes only waste rock and concentrator plant tailings (with by-products recovery), and excludes conversion plant tailings. The conversion plant tailings will be transported off-site to an appropriate disposal facility (facility selection process is in-progress). The following discussion relates to results specific to the actual planned waste materials. Results from LEAF and ASTM D 5744-96 (humidity cell) test methods provide information for identification of COPCs and for assessment of both short-term and long-term leaching potential from the proposed waste material. The LEAF testing, and long-term results from humidity cell leaching over extended periods, identify that pH values from initial leaching associated with the planned waste material (PAG waste rock, non-PAG waste rock, and concentrator plant tailings) are expected to be elevated above neutral.The pH values are sometimes in excess of applicable groundwater and surface water regulatory and/or guidance standards in the short-term LEAF tests (see Attachment 4 for LEAF test results summary table) and rarely and only marginally so in the very early phases of leaching in a few of the humidity cell samples (see Attachment 5). Comparison of the Attachment 4 and Attachment 5 tables indicates that the pH values for the LEAF test results are generally comparable to the pH values observed in the very early stages of the humidity cell testing (both are elevated above neutral, but the LEAF results more often exceed standards in a laboratory-induced condition), but humidity cell results (Attachment 5) indicate that the elevated pH values are quickly attenuated by the natural buffering capacity of the material and decrease to within regulatory standards within the first week of humidity cell testing. The long-term humidity cell test results, which involve the repeated introduction of MARSHALL MILLER&ASSOcmms,INc. 5 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►►' ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 oxygenated water, are expected to be most representative of actual site conditions at the PLCI mine site. The short-term elevated pH values of the leachate are associated with increased concentrations of Vanadium (V) and Aluminum (Al), as the solubility of those constituents is increased at those higher pH levels. In some LEAF test samples (where pH is greater than —9.3), those parameters in the leachate are elevated above regulatory standards for ground or surface waters (Attachment 4). In the humidity cells, the immediate ("first flush" or Week 0 leach event) on rare occasions exhibited a pH marginally higher than standards; however, twenty (20) to thirty (30) weeks of repeated leaching resulted in no exceedances of standards in V or Al concentrations (Attachment 6). Attachment 7 summarizes all instances where humidity cell test leachate exceeds the groundwater or surface water guidance values. The humidity cell results indicate that initially-elevated pH values (which generally are associated with higher concentrations of V and Al) drop to within standards by the next flushing event (Week 1). Both LEAF Method 1313 results and ASTM D 5744-96 (humidity cell) results consistently indicate that pH values from the waste material are likely to be initially elevated in the very early stages of waste placement. The results from both tests suggest that the temporarily-elevated pH values have the potential to result in elevated concentrations of V and Al, which are recognized as COPCs. However, only a small percentage of the LEAF test results (and none of the early humidity cell results) indicate concentrations for those parameters that exceed regulatory standards. In addition, the humidity cell results indicate that, under continuous waste disposal operations over time, the ever-increasing mass of disposal material allows for attenuation via the natural buffering capacity of the waste material that results in compliant pH and a diminishing rate of release of high-pH-soluble parameters (V and Al). The overall indication is that pH, V and Al are unlikely to exceed applicable regulatory and/or guidance standards in water passing through waste rock disposal facilities associated with the subject mine. The results also indicate that V and Al concentrations are a direct result of elevated pH, and therefore can be mitigated (if necessary) via commonly-implemented pH-control measures (see further discussion in subsequent section). Arsenic (As) occasionally shows up in leaching test results at concentrations greater than 10 µg/L (the drinking water and North Carolina groundwater standard), but at levels that are within the range of, and below, some of the levels shown to exist naturally in groundwater chemistry samples from monitoring wells in the project area. Unlike V and Al, As does not appear to correlate well with the pH of the leachate.Two of seven LEAF samples showed As at levels greater than 10 µg/L, and both of those included PAG waste rock (which is known to be limited to the East Pit Extension area and does not exhibit acidic conditions due to its inherent alkalinity, as shown by subsequent kinetic testing). In the humidity cell program, one of two mudstone samples (again, rock that was originally designated PAG, but does not yield acidic conditions) showed As to leach over the duration of the 20-week program. Drilling information indicates that mudstone is only expected to be present in the East Pit Extension area and is only expected to constitute a small percentage of the overall waste rock material. In contrast, amphibolite (estimated to represent the majority of waste rock in the entire mine) and schist MARSHALL MILLER&ASSOcmms,INc. 6 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►►' ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary April2023 (only present in the East Pit Extension) rock samples showed no leaching of As at concentrations exceeding standards. Importantly, groundwater samples collected by PLCI in April 2022 from the recently-installed site monitoring/pump test wells show As to commonly be present in the site groundwater, an observation that is generally consistent with publicly-available water quality data for the area. In the April 2022 groundwater samples, the As content exceeded the primary drinking water standard in approximately one-fourth of the wells,and in one well it occurred at a concentration similar to the highest concentrations seen in the leaching test results. Therefore, at the levels indicated by the test program results, Arsenic is considered to be within background levels common in this area of Gaston County and is not considered a COPC specific to the proposed project. The LEAF Method 1313 test results indicate the potential for Cobalt (Co)to be leachable, but only under certain geologic conditions and only where pH is lower than the expected range of approximately 7.5 to 8.5. LEAF results under natural conditions do not indicate exceedances of North Carolina surface and ground water guidelines for Co. Only one out of the 13 humidity cell tests indicated Co to be leachable at a concentration that exceeded the groundwater guideline.That one humidity cell test involved schist, a rock type that is only present in the East Pit Extension area. In summary, the LEAF Method 1313 and ASTM 5744-96 (humidity cell) test results indicate that the waste rock and concentrator tailings have the potential to create temporarily-elevated pH levels, and associated temporarily-elevated concentrations of some COPCs, in the earliest stages of material placement. However, the long-term humidity cell testing indicates that the temporarily-elevated pH values and associated slightly elevated COPC concentrations are quickly attenuated by the natural buffering capacity of the bedrock material. In addition, since the COPCs that are associated with elevated pH values are pH-dependent, pH-control mitigation measures are applicable. The results indicate that the potential for adverse effects to the environment are not expected and can be reduced or eliminated when pH is maintained between approximately 7.5 to 8.5 through a combination of the material's natural buffering capacity and pH control mitigation measures. In addition to the effects of temporarily-elevated pH (Al and V) in the early stages of waste disposal, certain test results indicate that As and Co are infrequently present under specific geologic and geochemical conditions. Of those, As concentrations from testing are associated only with mudstone and are within the range of As concentrations observed in local groundwater. Elevated Co concentrations can be expected to occur only at lower pH values outside the expected pH range for discharge from the waste material and only appear to be associated with schist, a rock type that is only present in the East Pit Extension area. MARSHALL MILLER&Assocmms,INc. 7 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary April2023 5 Operation Plan for Monitoring and Potential Mitigation for Waste Rock Disposal Areas and Backfilled Pits The current mine reclamation plan includes placement of waste rock and concentrator plant tailings in both above-ground disposal areas as well as in open pit mine areas where mining has been completed. Monitoring and mitigation (if necessary) strategies for each scenario are discussed below. In general, the results of the geochemical analyses completed for the waste rock and concentrator plant tailings (including, but not limited to, humidity cells and LEAF testing) indicate that long-term adverse environmental conditions are not expected to occur associated with either the above-ground waste disposal sites or the backfilled pits. As discussed in previous sections, the analysis indicates that there is a potential for water with elevated pH values (with associated increased concentrations of Al and V) to temporarily discharge from the waste material in early stages of placement, but long-term leach tests indicate that the natural buffering capacity of the material will attenuate both the pH and associated COPC concentrations to within regulatory guidance values. A conceptual flow diagram is included as Exhibit 1 to illustrate the concepts discussed below. 5.1 Above-Ground Waste Rock Disposal Area Design of the above-ground waste rock disposal areas inherently facilitates containment and monitoring of runoff from the waste material via site construction and stormwater runoff control measures. Prior to placement of material in the waste rock area, the native, low-permeability silt and clay-rich soil will be pre-compacted to reduce the potential for infiltration of runoff from the waste material into the underlying ground. Incremental placement of waste material onto the pre-compacted, low-permeability silt and clay-rich soil will provide additional densification and compaction of the soil as the waste disposal area is constructed. Rainwater that infiltrates through the waste material will percolate down to the base of the pile, be impeded by the low-permeability soil beneath the waste pile, and discharge to sediment control ponds that are part of the disposal area design. As the pile is constructed from the bottom upwards, each incremental level of the out-slope will be covered with soil and vegetated to progressively decrease the amount of infiltration. Upon completion of the final waste rock and tailings storage area, the top will be "domed" to create positive drainage, to decrease infiltration, and to reduce the potential for pooling of rainwater on the pile. Each sediment control pond is designed to collect runoff from a specific area of the waste rock pile, facilitating thorough monitoring of discharge. Water quantity and quality monitoring for above-ground waste disposal areas will be conducted for the inflow and outflow of sediment control ponds that are part of the existing waste rock pile design (monitoring will be done immediately upstream and downstream of the pond). In addition, monitoring wells positioned along the perimeter of the proposed mine area will be used to monitor for any adverse groundwater effects from the waste rock pile or other portions of the operation. Monitoring of water MARSHALL MILLER&ASSocmms,INC. 8 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 quality of the inflow to each sediment pond will allow PLCI to evaluate the need for temporary water treatment mitigation procedures on a regular basis. Monitoring of the outflow of each pond will allow PLCI to observe the quality of the final discharge, assess the performance of mitigation procedures, and adjust treatment as necessary. The sampling and testing will be conducted using industry-standard procedures and methods, and certified laboratories. Water quantity and quality monitoring for above- ground waste rock disposal areas will be completed monthly for the first six months of construction and quarterly thereafter, with the option to adjust the frequency of the monitoring based on observed conditions, and subject to review and approval by NC DEMLR. If water quality mitigation is required at a pond,the primary method will be pH adjustment using a low-pH additive, supplemented byflocculant addition if necessary. Adjustment of the pH of water is a common and effective mitigation strategy for a wide variety of mineral, hard rock, and surface mining projects. Upon completion of reclamation activities for above-ground waste disposal areas, water quantity and quality monitoring will be continued until hydrologic equilibrium is established and water quality parameters are stabilized and within regulatory or background ranges. 5.2 Pit Backfill Waste Rock Disposal Areas Placement of waste material into open-pit mining areas will start after mine pits are excavated to their planned completion depth by following the proposed reclamation plan reviewed and approved by DEMLR. During mining and backfilling of a pit, groundwater (and direct rainfall) will enter the pit, be collected, and be pumped out of the pit to a specifically designed pit discharge pond. As indicated on Exhibit 1,water from the pit discharge ponds may either be used at the concentrator plant or discharged to streams.The pit discharge ponds provide locations for monitoring water quality from the pit (and for conducting pH modifications as necessary) in the same way that water will be monitored in the sediment control ponds associated with the above-ground waste disposal area (previously discussed). Due to the reverse-gradient associated with the excavation of and pumping from the open pit, groundwater will flow into, and not out of,the pit up until the time that the water level in the backfilled pit is allowed to reach a level equal to, or greater than, the surrounding natural groundwater table. As a pit is progressively backfilled, groundwater and rainfall will infiltrate and accumulate in the waste material.As pit backfilling progresses, PLCI will monitor the water level and water quality characteristics of water accumulating in the backfill via a water collection and monitoring system (see Exhibit 2). The system will provide PLCI with the means to monitor and sample water in the backfill. The water collection and monitoring system also provides a means for dewatering the backfill, if necessary, in the event of adverse environmental impact. Pumping for mitigation purposes would establish a reverse- gradient condition and prohibit adverse water from moving away from the pit into the groundwater system. In the event that backfill dewatering is necessary for mitigation purposes (due to undesirably low or elevated pH and associated COPCs), water pumped from the backfill would be monitored and treated (pH control) at the pit discharge pond on a monthly basis (with the option to adjust the frequency of monitoring based on observed conditions) until the pH condition is attenuated by the natural buffering capacity of the material. MARSHALL MILLER&Assocmms,INc. 9 Leaching Environmental Assessment Framework(LEAF) and Accelerated Weathering of Solid Materials ►► ►► Using a Modified Humidity Cell(ASTM D 5744-96)Collaboration Technical Summary Apri12023 Upon completion of backfilling of a pit with waste rock and concentrator tailings to the elevation of the surrounding ground,the material will continue to be piled in a manner consistent with the construction specifications defined in the permit (in a similar manner to the construction of the above-ground waste rock disposal areas). As such, incremental levels of the pile on top of the backfilled pit will be covered with low-permeability soil and vegetated progressively to reduce infiltration and reduce excess stormwater runoff. Upon completion of the final above-ground pile on top of a backfilled pit, the top of the constructed pile will be domed to create positive drainage and reduce infiltration. Water monitoring from each backfilled pit will be continued after reclamation until hydrologic equilibrium is established and water quality parameters are stabilized and within regulatory or background ranges. MARSHALL MILLER&ASSocmms,INC. 10 Attachments Page intentionally left blank. Piedmont Lithium Attachment 1: Table of Applicable State and Federal Guidelines for Groundwater and Surface Water USEPA North Carolina North Carolina Drinking Water Ground Water Surface Water Standard Parameter Standard Standard Acute Chronic (Units:µg/L) Hg 2 1 0.012 0.012 Ag 100* 20 Calculate As 10 10 340 150 B 300 H.A. 700 34,000 TV 7,300 TV Ba 2,000 700 21,000 TV Be 4 4 65 6.50 Bi Cd 5 2 Calculate Co 1 16 TV 1.6 TV Cr+6=16 Cr+6=11 Cr 100 10 Calculate Cu 1,300 A.L. 1,000 Calculate Mo 51,000 TV Ni 100 H.A. 100 Calculate Pb 15 A.L. 15 Calculate Sb 6 1 5,300 TV Se 50 20 5 5 Sn 2,000 Sr 25,000 H.A. 2,000 Ti Th TI 2 2 u 30 V 7 W y Zr (Units:mg/L) Al 0.05-0.2* 0.75 0.30 Fe 0.3* 0.3 K Li Mg Mn 0.05* 0.05 Na P Si Zn 5* 1.00 Calculate SO4 250* 250 F 2* 2 68 2 Chloride 250* 250 230 230 Ca NO3 10 10 Acidity Alkalinity Hardness 100 (Units:pH in Standard Units,EC in µS/cm) pH 6.5-8.5 6.5-8.5 6-9 6-9 EC Drinking Water/ * Secondary Standard Groundwater H.A. Health Advisory A.L. Action Level Surface Calculate: Water quality standard for Water parameter depends upon water hardness. TV: In-stream target value Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results PAG Composite [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.1 (Note:The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH9 @pH8 @aH7 I @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 6.3 3.6 1.3B 7.6 17 12 8.9 1.5 8 DUP 8.2 8 DUP 32 8 DUP 15 DUP Ba <3.1 10 15 26 210 <3.1 <3.1 390 DUP Be <0.27 <0.27 <0.27 <0.27 1.3 <0.27 <0.27 4l8 DUP Cd <0.22 0.28 J <0.22 0.39 J <0.22 <0.22 <0.22 <0.22 DUP <0.22 DUP Co <0.26 0.51 2.9 B 35 35 <0.26 <0.26 8.4 8 DUP 68 8 DUP Cr,Total <1.5 <1.5 <1.5 <1.5 9.4 1.5 J <1.5 74 DUP <1.5 DUP Ni <0.52 0.23 22 100 150 0.66 J 0.59 J 0.741 DUP 9.6 DUP 52 DUP 200 DUP <0.52 DUP Pb <0.17 0.21 J <0.17 <0.17 1.1 0.59 J 2.5 <0.17 DUP 12 8 DUP 1.1 DUP Se <0.74 0.77 J <0.74 <0.74 <0.74 <0.74 <0.74 TI <0.47 0.64 J <0.47 <0.47 <0.47 <0.47 <0.47 0.551 DUP V 13 3.1 4.2 6.2 47 20 20 4.0 DUP 140 DUP 17 DUP (Units:mg/L) Acidity -17.9 -63.4 -68.5 10.7 150 -28 <5 -23.4 DUP -22.8 DUP 320 DUP 180 DUP -18 DUP Alkalinity 38 120 98 44 <5 37 38 61 DUP 50 DUP <5 DUP Al 0.57 0.073 0.045 0.360 5.400 1.400 1.500 0.0271 DUP 44.0 DUP Ca 20 93 120 280 240 5.5 4.5 68 DUP 180 DUP Fe 0.037 J <0.028 0.044 J 13.00 70.0 0.38 0.34 0.055 DUP 0.20 DUP 89.0 DUP 0.20 DUP 0.29 DUP K 12 12 16 16 24 8.6 8.7 16 DUP 7.9 DUP Li 0.19* 0.22* 0.26 B 0.34* 0.59 0.16 0.17 0.82 8 DUP Mg 2.3 5.5 6.8 9.6 17.0 0.55 0.39 J 24 DUP Mn 0.0017 J B 0.18 B 0.61 1.60 B 1.80 0.0054 0.0045 J 0.28 DUP Na 4 3.9 5.5 4.9 7.4 3.7 3.2 I1.0 DUP P <0.057 <0.057 <0.057 0.22 J 0.97 <0.057 <0.057 0.061 l DUP 15.0 DUP 1.1 DUP Si 2.5 3.9 6.9 16.0 31.0 3.5 3.3 45.0 DUP Zn <0.0029 0.0034 J <0.0029 0.037 0.10 0.0046 J 0.0032 J 0.0069 DUP 0.0063 DUP 0.21 DUP (Units:pH in Standard Units,EC in µS/cm) pH 9.4 7.9 7.3 5.5 4.3 9.8 9.8 SC 220 640 710 1800 1800 81 80 480 DUP 630 DUP 1900 DUP *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results non-PAG/PAG/Concentrator Tailings with By-Products [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.2 (Note: The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH9 @pH8 @pH7 I @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 1.3 1.0 5.8 7.3 6.8 5.9 DUP 4.2 DUP 2.7 DUP Ba 13 48 170 4.6 JB 4.3 J,B 91 DUP Be <0.27 <0.27 0.84 J <0.27 <0.27 <0.27 DUP Cd <0.22 <0.22 0.42 J <0.22 <0.22 0.25J DUP Co <0.26 0.40 J 33 <0.26 <0.26 32 DUP Cr,Total <1.5 <1.5 3.9 <1.5 <1.5 <1.5 DUP Ni <0.52 0.82 J 40 <0.52 <0.52 33 DUP Pb <0.17 <0.17 <0.17 <0.17 <0.17 <0.17 DUP Se <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 DUP TI <0.47 <0.47 0.63 J <0.47 <0.47 0.5 J DUP 0.571 DUP V 5.8 3.1 12 23 36 3.8 DUP 23 DUP (Units:mg/L) Acidity -16.6 -33.5 6.1 60 -15.1 -13.1 43 DUP Alkalinity 41 63 40 9.4 <5 36 37 52 DUP <5 DUP Al 0.2 0.024 J 2.6 1.1 1.6 1.1 DUP 1.4 DUP Ca 32 78 130 6.4 3.3 110 DUP 5.4 DUP Fe <0.028 <0.028 28.0 0.22 0.34 21.0 DUP 0.48 DUP K 7.8 11.0 14.0 9.1 8.8 14.0 DUP 9.8 DUP 9.3 DUP Li 2.0 B 1.7 B 0.49 0.22 0.28 0.44 DUP 0.20 DUP Mg 2.4 4.7 8.1 0.78 0.34 J 7.7 DUP 0.71 DUP Mn 0.0054 B 0.32 B 2.1 0.0029 J 0.0042 J 1.8 DUP Na 9.3 11.0 5.1 4.2 5.2 4.8 DUP 5.0 DUP P <0.057 <0.057 4.8 0.0811 0.111 2.6 DUP 0.1 J DUP Si 3.1 7.3 22.0 3.0 3.7 18.0 DUP Zn <0.0029 <0.0029 0.11 <0.0029 <0.0029 0.078 DUP (Units:pH in Standard Units,EC in µS/cm) pH 8.9 7.5 6.6 5.8 4.5 9.2 9.6 5.1 DUP 9.3 DUP SC 200 450 530 1000 1100 93 80 330 DUP 89 DUP *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results PAG/Concentrator Tailings with By-Products [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.3 (Note: The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH9 @pH8 @pH7 I @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 8.9 13 3.4 5.6 34 22 32 5.7 DUP 3.9 DUP 7.1 DUP 14 DUP 29 DUP Ba <3.1 7.2 J 18 46 170 <3.1 6.2 J Be <0.27 <0.27 <0.27 <0.27 3.1 <0.27 <0.27 Cd <0.22 <0.22 <0.22 0.35 J 0.53 J <0.22 <0.22 Co <0.26 <0.26 0.66 43 64 <0.26 0.45 J 1.6 DUP Cr,Total <1.5 <1.5 <1.5 <1.5 74 <1.5 2.1 Ni 0.83 J 0.95 J 4.9 13.0 210 0.86 J 1.6 16 DUP 1.1 DUP Pb <0.17 <0.17 <0.17 <0.17 1.1 <0.17 0.27 J Se <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 TI <0.47 <0.47 <0.47 <0.47 <0.47 <0.47 <0.47 V 8.9 2.8 1.8 5.0 49 17 27 7.0 DUP 3.0 DUP 20 DUP (Units:mg/L) Acidity -17.6 -31.9 -15.2 8.1 160 -6.71 <5 <5 DUP -36.4 DUP -21.6 DUP <5 DUP -12.9 DUP Alkalinity 38 73 94 35 <5 33 37 64 DUP 74 DUP 9.1 DUP Al 0.84 0.14 0.028 J 0.51 6.50 1.3 2.3 0.77 DUP 0.18 DUP <0.016 DUP 1.7 DUP Ca 8.2 48 120 250 190 6.0 4.2 10.0 DUP 84 DUP Fe 0.11 <0.028 <0.028 19.0 58.0 0.19 0.74 <0.028 DUP 0.36 DUP 0.49 DUP K 8.9 13.0 11.0 18.0 17.0 11.0 12.0 9.3 DUP I1.0 DUP 14.0 DUP Li 0.15 0.18 B 3.10 B 0.45 B 0.49 0.18 0.20 0.21 DUP Mg 0.9 3.7 3.7 9.3 11.0 0.55 0.56 1.1 DUP 2.8 DUP 4.8 DUP 0.63 DUP Mn 0.0017 J 0.067 B 0.29 B 2.5 B 2.4 0.0022 J 0.0086 0.82 DUP 0.0057 DUP Na 3.2 3.9 11.0 5.0 4.7 5.2 6.3 2.9 DUP 2.8 DUP 3.8 DUP 5.4 DUP P <0.057 <0.057 <0.057 <0.057 4.9 <0.057 <0.057 Si 2.2 3.2 7.1 17.0 23.0 3.1 4.7 2.6 DUP 5.7 DUP 3.9 DUP Zn <0.0029 <0.0029 0.0043 J 0.056 0.12 <0.0029 0.0031 (Units:pH in Standard Units,EC in µS/cm) pH 9.3 8.0 7.4 5.6 3.8 9.4 9.6 6.9 DUP SC 180 480 610 18 1700 96 92 370 DUP 1700 DUP *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results Sample 1-Concentrator Tailings with By-Products [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.4 (Note: The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH9 @pH8 @pH7 I @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 0.801 0.65 J 0.811 5.2 2.1 2.3 1.3 DUP 1.9 DUP Ba <3.1 8.3 J 18 99 <3.1 4.6 JB 78 DUP <3.1 DUP Be <0.27 0.35 J 3 17 <0.27 <0.27 Cd <0.22 0.49 J 1.7 3.3 <0.22 <0.22 2.0 DUP Co <0.26 5.5 26 59 <0.26 <0.26 6.9 DUP Cr,Total <1.5 <1.5 <1.5 410 <1.5 <1.5 4.5 DUP 310 DUP Ni <0.52 29 130 390 <0.52 <0.52 33 DUP 340 DUP Pb <0.17 <0.17 <0.17 0.37 J <0.17 <0.17 Se <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 0.791 DUP TI <0.47 0.75 J 0.95 J 1.7 <0.47 <0.47 1.1 DUP 1.4 DUP V 0.94 J <0.78 <0.78 13 2.9 2.7 1.0 DUP 0.851 DUP 9.4 DUP 2.4 DUP 3.6 DUP (Units:mg/L) Acidity -38.4 -31.1 140 200 -18.3 -13.1 -10.7 DUP 240 DUP -11.0 DUP Alkalinity 52 54 8.6 <5 36 36 30 DUP <5 DUP Al 0.14 0.028 J 0.88 4.70 B 0.59 0.65 0.099 DUP 1.3 8 DUP 4.10 DUP 0.50 DUP 0.71 DUP Ca 28 88 110 130 7.5 6.5 74 DUP 5.6 DUP Fe 0.035 J 0.063 50.0 120.0 0.057 0.087 0.094 DUP 1.70 DUP 62.0 DUP 0.061 DUP K 4.9 6.9 7.3 9.2 5.0 4.5 5.8 DUP 8.5 DUP 7.6 DUP Li 0.26 B 0.93 B 1.50 B 2.30 0.27 0.25 0.69 DUP 1.50 DUP 1.70 DUP Mg 1.3 3.2 4.0 4.9 0.5 0.43 J 2.9 DUP Mn 0.17 B 9.0 B 16.0 B 23.0 0.011 0.0091 8.2 DUP 17.0 DUP 0.0071 DUP Na 3.3 4.7 4.5 5.4 4.4 3.8 3.9 DUP 5.2 DUP 4.6 DUP 4.2 DUP P 0.081 J <0.057 <0.057 2.0 J 0.27 J 0.241 4.0 DUP Si 3.4 9.5 14.0 21.0 3.4 3.3 8.0 DUP Zn <0.0029 0.017 0.28 0.61 B <0.0029 <0.0029 0.043 DUP 0.59 DUP (Units:pH in Standard Units,EC in µS/cm) pH 8.1 6.5 5.5 4.0 9 8.9 7.3 DUP 8.8 DUP SC 290 760 1200 1700 87 74 560 DUP 1500 DUP *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results non-PAG/Concentrator Tailings with By-Products [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAFS (Note:The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH9 @pH8 @aH7 I @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 0.66 J 0.39 J 0.30 J 0.47 J 5.5 0.79 J 1.3 <0.28 DUP Ba 9.7 J 18 73 150 350 5.2 JB 6.5 JB 28 DUP 48 DUP 110 DUP Be <0.27 <0.27 <0.27 <0.27 5.1 <0.27 <0.27 Cd <0.22 <0.22 <0.22 0.45 J 0.59 J <0.22 <0.22 Co <0.26 <0.26 1.4 21 30 <0.26 <0.26 0.261 DUP Cr,Total <1.5 <1.5 <1.5 <1.5 85 <1.5 <1.5 Ni <0.52 <0.52 1.2 18 26 <0.52 <0.52 0.791 DUP 14 DUP Pb <0.17 <0.17 <0.17 <0.17 0.31 J <0.17 <0.17 Se <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 TI <0.47 <0.47 <0.47 0.66 J 1.3 <0.47 <0.47 V 7.4 5.2 1.4 2.9 98 20 34 8.4 DUP 1.5 DUP 4.0 DUP 3.5 DUP (Units:mg/L) Acidity -20.8 -29.9 -31.9 28 150 <5 -23.0 <5 DUP -54.4 DUP 15 DUP -7.1 DUP -5.54 DUP Alkalinity 35 41 39 <5 <5 35 36 56 DUP 73 DUP 7.7 DUP Al 0.30 B 0.17 B <0.016 0.43 12.0 1.60 1.90 0.39 B DUP 0.034 DUP 0.029 JB DUP 0.18 DUP 0.94 DUP 1.70 DUP Ca 14 23 44 84 150 4.8 3.5 9.4 DUP 33 DUP 5.7 DUP 3.0 DUP Fe <0.028 0.042 J <0.028 18.0 46.0 0.15 0.73 0.028 J DUP 9.5 DUP 0.48 DUP K 9.2 9.8 7.9 11.0 16.0 7.6 7.5 8.6 DUP 5.1 DUP 11.0 DUP 8.1 DUP Li 0.23 0.25 0.22 0.47 0.84 B 0.22 0.26 0.19 DUP 0.10 DUP 0.31 DUP Mg 1.7 2.6 3.0 5.4 11.0 0.61 0.48J 1.1 DUP 1.9 DUP 3.9 DUP Mn 0.013 0.056 1.40 2.60 3.20 B 0.0023 J 0.0089 0.0049 J DUP 0.16 DUP 0.71 DUP 0.0061 DUP Na 4.0 3.9 3.6 4.2 6.7 3.9 5.2 4.0 DUP P <0.057 <0.057 <0.057 0.12 J 12.0 0.098 J 0.17 Si 2.6 3.1 5.1 14.0 35.0 2.5 4.1 2.2 DUP 2.7 DUP 5.8 DUP Zn <0.0029 <0.0029 0.0035 0.081 0.23 <0.0029 <0.0029 0.004 J DUP 0.054 DUP (Units:pH in Standard Units,EC in µS/cm) pH 8.6 8.1 6.8 5.5 3.6 9.2 9.6 7.7 DUP 7.3 DUP 6.0 DUP SC 180 470 360 750 1700 87 75 270 DUP 700 DUP 76 DUP *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results Composite#1,#2,and#3 (Waste Rock) [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.6 (Note: The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH8 @pH7 @pH5.5 I @pH4 SPLP Natural (Units:µg/L) As 0.37J 0.42J 0.52J 1.9 0.511 0.69J Ba 69 180 470 980 22 27 Be <0.27 <0.27 <0.27 2.4 <0.27 <0.27 Cd <0.22 <0.22 0.30 J 0.70 J <0.22 0.25 J Cr,Total <1.5 <1.5 <1 s <1.5 <1.5 <1.5 Ni <0.52 <0.52 11 17 <0.52 <0.52 Pb <0.17 <0.17 <0.17 0.26 J <0.17 <0.17 0.241 DUP Se <0.74 <0.74 <0.74 <0.74 <0.74 <0.74 TI <0.47 0.47 J 0.81 J 1.8 <0.47 <0.47 1.4 DUP Co <0.26 1.4 44 79 <0.26 <0.26 87 DUP V 2.5 1.5 1.7 8.9 8.9 5.2 2.2 DUP 2.4 DUP 17 DUP 5.0 DUP 6.8 DUP (Units:mg/L) Acidity -21.1 -22.7 12 19 7.8 -14.8 36 DUP -9.71 DUP Alkalinity 36 31 5 <5 33 36 Al 0.060 <0.016 0.150 3.90 1.10 0.71 Ca 22 36 77 140 7.10 8.60 Fe 0.076 0.055 3.10 22.0 0.570 0.310 <0.028 DUP <0.028 DUP 0.48 DUP K 8.6 9.50 13.0 15.0 6.50 6.10 Li 0.120 0.120 0.350 0.54 0.084 0.06 0.057 DUP Mg 3.40 5 6.90 9.60 1.10 1.10 Mn 0.120 1.30 2.90 4.30 0.0078 0.0081 0.012 DUP Na 3.40 3.40 4.00 4.60 3.50 3.20 P <0.057 <0.057 0.058 J 0.95 <0.057 <0.057 1.5 DUP Si 3.8 6.60 14.00 56.00 3.70 3.10 28 DUP Zn 0.0029 J 0.003 J 0.046 0.200 <0.0029 <0.0029 (Units:pH in Standard Units,EC in µS/cm) pH 7.9 7.0 4.2 9.0 8.7 SC 200 340 630 1200 89 97 *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 2: LEAF Method 1313 Screening Results Concentrator Tailings without By-Products [Results for Duplicate(DUP)Substantially Similar except as Noted] LEAF.7 (Note:The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests,and should not be used as such.Instead,LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) pH-controlled screening tests Parameter @pH8 @pH7 @pH5.5 @pH4 SPLP Natural (Units:µg/L) As 0.901 0.96 J 2.1 1.9 0.92 J O.801 DUP Ba <3.1 <3.1 3.3 J 18 <3.1 <3.1 Be <0.27 <0.27 1.0 7.3 <0.27 <0.27 8.1 DUP Cd <0.22 <0.22 0.27 J 0.46 J <0.22 <0.22 Co <0.26 0.27 J 0.48 J <0.26 <0.26 0.63 DUP Cr,TotaI <1.5 <1.5 <1.5 <1.5 <1.5 1.7J Ni <0.52 <0.51 3.9 7.1 <0.52 0.57J Pb 1.2 0.17 0.82 J ^" 1.7 0.991 DUP Se <0.74 <0.7ti <0.74 <0.74 <0.74 <0.74 TI <0.47 <0.47 <0.47 <0.47 <0.47 <0.47 V 0.86 0.99 J 0.84 J 0.88 J 0.80 J <0.78 <0.78 DUP <0.78 DUP 1.1 DUP 0.85 J DUP (Units:mg/L) Acidity <5 <5 8 23 20 14 12 DUP 23 DUP Alkalinity 7.3 <5 <5 <5 <5 6.8 5.7 DUP Al 0.460 0.220 0.058 0.490 0.280 0.750 0.340 DUP 0.32 DUP Ca 1.60 2.00 6.00 11.00 1.70 1.20 Fe 0.077 0.079 0.055 0.440 0.078 0.120 0.054 DUP 0.50 DUP 0.096 DUP 0.11 DUP K 0.65 0.67 0.76 1.00 0.54 0.54 Li 0.038 0.037 0.098 0.190 0.028 0.036 Mg 0.1601 0.22 J 0.35 J 0.43 0.18 J 0.111 Mn 0.026 0.078 0.820 1.700 0.044 0.017 1.90 DUP Na 1.40 1.30 1.40 1.60 1.60 1.30 P 0.071 J 0.160 J 0.910 2.50 0.077 J 0.066 J Si 1.60 1.40 1.80 2.40 1.70 2.00 Zn 0.00461 0.005 0.049 0.110 0.0036 J 0.00411 (Units:pH in Standard Units,EC in µS/cm) pH 8.3 4.2 7.7 9.0 LSE 18 52 55 130 20 *Calibration Blank Outside Acceptance Limits J -Approximate value,greater than Method Detection Limit but less than Reporting Limit. B-Compound found in both blank and sample. Piedmont Lithium Attachment 3: Summary of 2019 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) Waste Rock 205-7 HC.1 Leachate Week of Peak Final Week Parameter Concentration Range I Concentration Concentration (Units:µg/L) Hg ND(<0.01) - 0.01 15 ND(<0.01) Ag ND(<0.05)µg/L throughout As ND(<0.2) - 0.2 0 ND(<O.2) B ND(<2) 4 1 ND(<2) Ba 0.22 - 0.7 0 0.22 Be ND(<0.007) 0.008 3 ND(<0.007) Bi ND(<0.007)µg/L throughout Cd ND(<0.003) 0.015 5 0.009 Co ND(<0.004) - 0.025 15 ND(<0.004) Cr ND(<0.08)µg/L throughout Cu ND(<0.2) 0.5 0 0.15 Mo 0.95 12.4 5 9.11 Ni ND(<0.1) 0.2 1 0.1 Pb ND(<0.01) - 0.06 1 0.03 Sb ND(<0.9)µg/L throughout Se ND(<0.04) - 0.15 0 ND(<0.04) Sn ND(<0.06) 0.25 0 ND(<0.06) Sr 3.63 6.24 0 3.82 Ti ND(<0.05) 0.24 0 0.20 Th ND(<0.1) - 0.9 1 ND(<0.1) TI ND(<0.005) 0.023 0 ND(<0.005) U 0.031 - 0.272 20 0.272 V 0.3 1.99 0 0.40 W ND(<0.02) - 0.19 0 ND(<0.02) Y ND(<0.002) 0.008 0 0.004 Zr ND(<2)µg/L throughout (Units:mg/L) Al 0.057 0.111 0 0.067 Fe ND(<0.007) - 0.007 0 ND(<0.007) K 0.13 1.8 0 0.130 Li 0.0095 0.317 0 0.0095 Mg 0.177 0.242 15 0.190 Mn 0.00110 0.00524 2 0.00340 Na 0.16 2.28 0 0.16 P ND(<0.003) 0.016 20 0.016 Si 0.38 0.47 1 0.43 Zn ND(<0.002)mg/L throughout SO4 ND(<0.2) 0.5 0 ND(<0.2) F Chloride Ca Not analyzed NO3 Not analyzed Acidity ND(<2)mg/L throughout Alkalinity 9 22 1 0 1 11 Hardness I I Not analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.98 8.01 0 7.15 EC 20 - 44 0 1 22 Piedmont Lithium Attachment 3: Summary of 2019 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) Waste Rock 212-6 HC.2 Leachate Week of Peak Final Week Parameter Concentration Range I Concentration Concentration (Units:µg/L) Hg ND(<0.01)µg/L throughout Ag ND(<0.05)µg/L throughout As 0.3 1.1 0 0.3 B ND(<2) 4 1 ND(<2) Ba 0.61 - 3.38 0 0.61 Be ND(<0.007) 0.013 3 ND(<0.007) Bi ND(<0.007) - 0.008 1 ND(<0.007) Cd ND(<0.003) 0.010 3 ND(<0.003) Co 0.013 0.048 0 0.030 Cr ND(<0.08) 0.19 20 0.19 Cu ND(<0.2) 2 15 ND(<0.2) Mo 1.61 - 20.5 3 5.36 Ni ND(<0.1) 0.6 1 0 1 0.1 Pb ND(<0.01) - 0.13 1 1 0.01 Sb ND(<0.9)µg/L throughout Se ND(<0.04) - 0.42 0 ND(<0.04) Sn ND(<0.06) 0.2 3 ND(<0.06) Sr 8.32 - 15.7 0 9.27 Ti 0.08 0.38 1 0.08 Th ND(<0.1) - 0.3 2 ND(<0.1) TI 0.011 0.069 0 0.011 U 0.015 3.47 5 0.204 V 0.14 0.59 0 0.20 W ND(<0.02) - 0.19 1 ND(<0.02) Y ND(<0.002) 0.014 20 0.014 Zr ND(<2)µg/L throughout (Units:mg/L) Al 0.059 0.094 10 0.061 Fe ND(<0.007) - 0.008 1 ND(<0.007) K 0.424 7.89 0 0.424 Li 0.0171 - 0.589 0 0.0171 Mg 0.422 0.784 5 0.422 Mn 0.00227 - 0.00637 3 0.00321 Na 0.08 2.13 0 0.09 P ND(<0.003) 0.012 20 0.012 Si 0.52 0.66 5 0.55 Zn ND(<0.002)mg/L throughout SO4 1.9 6.2 0 2.4 F Chloride Ca Not analyzed NO3 Not analyzed Acidity ND(<2)mg/L throughout Alkalinity 10 24 1 0 1 11 Hardness I I Not analyzed (Units:pH in Standard Units,EC in µS/cm) pH 7.07 7.77 0 7.10 EC 27 - 82 0 1 31 Piedmont Lithium Attachment 3: Summary of 2019 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) Tailings 4(Concentrator Tailings without By-Products) HC.3 Leachate Week of Peak Final Week Parameter Concentration Range I Concentration Concentration (Units:µg/L) Hg ND(<0.01) - 0.01 1 5 ND(<0.01) Ag ND(<0.05)µg/L throughout As 0.4 - 1.3 1 0.4 B ND(<2) 9 1 ND(<2) Ba 0.25 2.76 3 0.92 Be 0.009 0.034 20 0.034 Bi ND(<0.007) - 0.017 0 ND(<0.007) Cd ND(<0.003) 0.032 1 0.009 Co ND(<0.004) - 0.027 0 ND(<0.004) Cr ND(<0.08) 0.66 2 ND(<0.08) Cu ND(<0.2) 3 0 ND(<0.2) Mo 0.24 - 26.5 5 0.31 Ni ND(<0.1) 0.3 0 ND(<O.1) Pb 0.01 - 0.16 1 0.04 Sb ND(<0.9) 1.1 2 ND(<0.9) Se ND(<0.04) - 0.05 0 ND(<0.04) Sn 0.11 0.43 0 0.13 Sr 1.59 11.9 2 2.03 Ti ND(<0.05) 0.19 1 ND(<0.05) Th ND(<0.01) - 0.1 2 ND(<0.01) TI 0.006 0.048 1 0.006 u 0.046 12.2 1 0.046 V 0.16 0.47 1 0.16 w ND(<0.02) - 0.25 1 ND(<0.02) y ND(<0.002) 0.011 5 0.003 Zr ND(<2)µg/L throughout (Units:mg/L) Al 0.007 0.55 1 0 0.007 Fe ND(<0.007)mg/L throughout K 0.077 1.12 1 0.119 Li 0.0093 0.135 2 0.0118 Mg 0.043 0.448 2 0.043 Mn 0.0005 0.0219 20 0.0219 Na 0.07 5.35 1 0.11 P 0.034 - 0.131 20 0.131 Si 0.47 1.76 2 0.68 Zn ND(<0.002) - 0.004 0 0.003 SO4 ND(<0.2) 1.4 0 ND(<0.2) F Chloride Ca Not analyzed NO3 Not analyzed Acidity ND(<2) - 2 15 ND(<2) Alkalinity 2 21 2 2 Hardness Not analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.34 7.27 5 6.34 EC 4 - 42 1 1 5 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 20-350-ABA8(Schist) H C.4 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 1.2 - 7.3 20 7.3 B <2 6 2 <2 Ba 0.32 - 1.06 0.32 Be <0.007 N/A <0.00 Bi <0.01 - 0.05 2 <0.01 Detected only once Cd <0.003 0.011 1 <0.003 Detected only twice Co 0.039 0.233 1 0.058 Cr <0.08 0.14 20 0.14 Cu <0.2 2.2 0 <0.2 Mo 0.11 - 5.05 1 0.23 Ni 0.2 2.7 0 0.2 Pb <0.09 0.15 4 <0.09 Sb <0.9 N/A <0.9 Se 0.08 - 0.42 0 0.11 Sn <0.06 0.24 0 <0.06 Sr 4.87 - 14 1 4.87 Ti 0.16 1.38 0 0.31 Th <0.1 N/A <0.1 TI <0.005 - 0.055 2 <0.005 U 0.213 0.743 1 0.301 V 0.52 0.71 0 0.53 W 0.06 - 0.65 0 0.06 Y <0.2 0.11 0 <0.02 Detected only twice Zr <2 N/A <2 (Units:mg/L) Al 0.029 - 0.065 0 0.029 Fe <0.007 0.017 0 0.007 K 0.562 - 3.94 1 0.562 Li 0.016 0.230 1 0.016 Mg 0.260 0.578 1 0.294 Mn 0.00261 0.0086 0 0.00261 Na 0.14 - 6.24 1 0.14 P <0.003 0.013 20 0.013 Si 0.26 - 0.38 4 0.28 Zn <2 N/A <2 SO4 5 - 38 1 5 Static F - - Not Analyzed Chloride Not Analyzed Ca Not Analyzed NO3 - - Not Analyzed Acidity <2 N/A <2 Alkalinity 4 - 13 0 5 Static Hardness Not Analyzed (Units:pH in Standard Units,EC in MS/cm) pH 6.91 - 8.32 1 0 7.2 Static EC 1 25 102 1 1 25 Static Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 20-363-ABA6(Mudstone) H C.5 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 0.5 - 2.1 15 1 B <2 4 2 <2 Ba 0.13 0.82 1 0.13 Be <0.007 0.009 2 <0.007 Detected only once Bi <0.01 N/A <0.01 Cd <0.003 - 0.015 2 <0.003 Co 0.090 0.0149 3 0.1 Cr <0.08 0.12 N/A 0.12 Detected only once Cu <0.2 0.4 0&1 <0.2 Mo 0.06 - 4.37 3 0.06 Ni 0.3 1.7 0 0.3 Pb <0.09 0.3 1 <0.09 Detected only twice Sb <0.9 N/A 0.04 Se <0.04 - 0.24 0 0.04 Sn <0.06 0.33 0 <0.06 Sr 11.3 32.2 2 11.3 Ti 0.11 1.35 5 0.27 Th <0.1 - 0.1 1 <0.1 Detected only once TI <0.005 0.033 2 <0.005 U 0.075 0.699 2 0.243 V 0.47 1.3 3 0.47 W <0.02 - 0.67 0 <0.02 Y <0.02 N/A <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.018 - 0.085 1 0.021 Fe <0.007 0.012 1 <0.007 K 0.098 0.606 0 0.08 Li 0.0185 0.220 2 0.0185 Mg 0.0406 - 0.922 3 0.406 Mn 0.00512 0.0192 2 0.00512 Na 0.08 1.64 0 0.08 P <0.003 0.059 1 0.011 Si 0.25 0.53 2 0.25 Zn <0.002 0.013 1 <0.002 Detected only twice SO4 11 - 21 7&8 12 Static F - Not Analyzed Chloride - - Not Analyzed Ca 5.57 8.98 2 5.57 NO3 - - Not Analyzed Acidity <2 N/A <2 Alkalinity 3 - 16 1 2 1 5 Static Hardness - Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.86 - 7.88 1 1 7.18 EC 1 41 - 69 1 2 1 48 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 21-408-ABA5 (Schist) H C.6 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.1 Ag <0.05 N/A <0.05 As 1.3 - 5.6 15 4.1 B <2 7 1&2 <2 Ba 0.39 1.09 0 0.39 Be <0.007 0.017 0&1 <0.007 Bi <0.01 - 0.04 2 <0.01 Detected only once Cd <0.003 0.008 2 0.003 Co 0.050 0.181 0 0.095 Cr <0.08 0.10 15&20 0.10 Cu <0.2 1.1 0 0.3 Mo 0.20 4.78 1 0.33 Ni 0.3 4.5 0 0.3 Pb <0.09 N/A <0.09 Sb <0.9 N/A <0.9 Se 0.06 - 0.6 0 0.06 Sn <0.06 0.28 0 <0.06 Sr 12.6 30 0 12.6 Ti <0.005 0.72 0 0.07 Th <0.1 N/A <0.1 TI <0.005 - 0.034 0 <0.005 U 0.699 1.85 2 0.716 V 0.13 0.33 0 0.13 W 0.05 0.9 0 0.05 Y <0.02 0.05 0 <0.02 Detected only once Zr <2 N/A <2 (Units:mg/L) Al 0.025 - 0.066 0 0.05 Fe <0.007 0.013 0 <0.007 Detected only once K 0.467 - 4.27 0 0.467 Li 0.0062 0.108 1 0.002 Mg 0.240 0.670 0 0.24 Mn 0.0073 0.0193 0 0.0175 Na 0.05 5.08 0 0.05 P <0.003 0.008 0,1,&20 0.008 Si 0.28 0.45 0 0.28 Zn <0.002 0.003 2 <0.002 Detected only once SO4 12 - 26 0&1 16 Static F - Not Analyzed Chloride Not Analyzed Ca Not Analyzed NO3 - Not Analyzed Acidity <2 N/A <2 Alkalinity <2 - 20 1 0 1 <2 Static Hardness - Not Analyzed (Units:pH in Standard Units,EC in MS/cm) pH 6.86 - 7.96 1 1 7.12 1 Static EC 1 14 105 1 1 14 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 21-408-ABA6(Amphibolite) H C.7 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 0.9 - 3.5 15 3.2 B <2 3 0&2 <2 Ba 0.34 - 0.47 1&3 0.35 Be <0.007 0.013 2 <0.007 Detected only once Bi <0.01 N/A <0.01 Cd <0.003 - 0.006 1 <0.03 Co 0.074 - 0.226 0 0.158 Cr <0.08 0.13 2 0.08 Cu <0.2 0.7 0 0.3 Mo 0.11 - 1.36 1 0.36 Ni 0.4 4.7 0 0.5 Pb <0.09 N/A <0.09 Sb <0.9 N/A <0.9 Se <0.04 - 0.21 0 <0.04 Sn <0.06 0.22 0 <0.06 Sr 5.78 24.7 0 5.78 Ti 0.14 0.53 1 0.14 Th <0.1 n/a <0.1 TI <0.005 - 0.019 20 <0.005 U 0.009 0.032 10 0.01 V 0.39 0.58 0&2 0.39 W 0.24 - 9.78 2 0.24 Y <0.02 N/A <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.027 - 0.052 0 0.027 Fe <0.007 0.01 2 <0.007 Detected only twice K 0.447 - 0.912 0 0.56 Li 0.0084 0.0406 2 0.0084 Mg 0.182 - 0.588 0 0.182 Mn 0.00123 0.00604 0 0.00123 Na 0.19 1.65 0 0.19 P <0.003 0.018 20 0.018 Detected only once Si 0.26 - 0.39 3 0.27 Zn <0.002 0.002 20 0.002 SO4 3 15 0 3 Static F - - Not Analyzed Chloride Not Analyzed Ca 2.10 7.60 0 2.22 NO3 - - Not Analyzed Acidity <2 3 4 <2 Alkalinity <2 - 13 1 <2 Static Hardness Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.50 - 7.71 1 1 6.77 EC 1 16 61 1 0 1 16 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 21-408-ABA11(Amphibolite) H C.8 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 1.5 - 6.5 20 6.5 B <2 3 2&3 <2 Ba 0.1 - 0.24 0 0.13 Be <0.007 0.015 2 <0.007 Detected only once Bi <0.01 N/A <0.01 Cd <0.003 - 0.009 5 <0.003 Detected only twice Co 0.016 - 0.068 0 0.19 Cr <0.08 0.15 0 0.1 Cu <0.2 1.2 0 <0.2 Mo 0.11 - 2.73 1 0.22 Ni <0.1 0.8 0 <0.1 Pb <0.09 N/A <0.09 Sb <0.9 N/A <0.9 Se <0.04 - 0.12 0 <0.04 Sn <0.06 0.34 0 <0.06 Sr 9.01 - 19.3 0 9.01 Ti 0.14 3.1 0 0.14 Th <0.1 N/A <0.1 TI <0.005 - 0.008 2 <0.005 Detected only once U 0.015 0.035 4 0.02 V 1.28 2.05 0 1.28 W 0.05 0.64 0 0.05 Y <0.02 N/A <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.036 - 0.107 0 0.052 Fe <0.007 0.029 0 <0.007 K 0.132 - 0.705 0 0.159 Li 0.0071 0.0561 1 0.0071 Mg 0.241 - 0.369 0 0.259 Mn 0.00181 0.00469 1 0.00181 Na 0.09 3.32 0 0.09 P <0.003 0.015 20 0.015 Si 0.33 0.48 0&3 0.35 Zn <0.002 N/A <0.002 SO4 <2 - 3 1&2 <2 F - Not Analyzed Chloride Not Analyzed Ca Not Analyzed NO3 - - Not Analyzed Acidity <2 N/A <2 Alkalinity 5 - 22 0 8 Hardness Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 1 7.33 8.95 1 1 7.45 1 Below 8 at week 1 EC 1 18 52 1 0 1 20 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 20 Weeks) 21-408-ABA13 (Mudstone) H C.9 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 20) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 4.1 - 24.2 15 22.7 B <2 23 2 <2 Ba 0.14 - 0.65 2 0.14 Be <0.007 0.074 2 <0.007 Bi <0.01 - 0.1 2 <0.01 Cd <0.003 0.080 2 0.003 Co 0.028 0.2 2 0.05 Cr <0.08 0.19 2 0.08 Cu <0.2 0.7 0 <0.2 Mo 0.08 0.8 10 0.18 Ni 0.1 0.7 0 0.1 Pb <0.09 0.44 2 <0.09 Sb <0.9 1.1 2 <0.9 Detected only once Se <0.04 - 0.36 2 0.05 Sn <0.06 0.43 0 <0.06 Sr 16.5 26.6 0 17.4 Ti 0.1 0.95 2 0.12 Th <0.1 N/A <0.1 TI <0.005 - 0.15 2 <0.005 Detected only once U 0.012 - 0.071 15 0.050 V 0.7 1.64 1 0.70 W 0.27 - 3.9 0 0.27 y <0.02 0.02 2 <0.02 Detected only once Zr <2 N/A <2 (Units:mg/L) Al 0.027 - 0.063 0 0.028 Fe <0.007 0.02 2 <0.007 K 0.048 0.31 0 0.074 Li 0.0295 0.471 0 0.0295 Mg 0.019 0.333 0 0.325 Mn 0.00147 0.00439 4 0.00249 Na 0.12 - 4.93 0 0.12 P <0.003 0.018 20 0.018 Si 0.34 - 0.45 3 0.34 Zn <0.002 0.012 2 <0.002 SO4 5 12 0&20 7 F - Not Analyze Chloride Not Analyze Ca Not Analyze NO3 - Not Analyze Acidity <2 N/A <2 Alkalinity 7 - 30 1 0 1 8 Static Hardness - Not Analyze (Units:pH in Standard Units,EC in µS/cm) pH 1 7.18 8.97 1 1 7.S7 EC 1 32 71 1 0 1 34 1 Below 50 after week 0 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 25 Weeks) 20-350-ABA6(Schist) HC.10 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 25) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 0.4 - 1.4 15 0.6 Elem.An.140 µg/g B <2 12 4 <2 Ba 0.36 - 1.29 0 0.39 Be <0.007 0.012 2 0.011 Bi <0.01 N/A <0.01 Cd 0.003 - 0.026 20 0.026 Co 0.513 5.39 0 1.33 Cr <0.08 0.13 1 <0.08 Cu <0.2 1.9 0 <0.2 MO 0.06 - 0.34 1 0.22 Ni 3.2 49.2 0 5.3 Pb <0.09 0.15 0 <0.09 Detected only in week 0 Sb <0.9 N/A <0.9 Se 0.26 - 1.16 1 0.33 Sn <0.06 0.29 0 <0.06 Sr 15.2 - 56.7 1 15.2 Ti <0.05 0.12 1 <0.05 Th <0.1 - 0.1 5 <0.1 Detected only once TI <0.005 0.017 2 <0.005 U 0.119 0.506 2 0.119 V <0.01 0.08 2&3 <0.01 W <0.02 - 0.16 1 <0.02 Y <0.02 3 0 <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.008 0.038 3 0.008 Fe <0.007 0.104 15 0.021 K 0.302 - 3.72 0 0.302 Li 0.0054 0.0365 1 0.0054 Mg 0.263 2.32 1 0.263 Mn 0.0173 0.0735 15 0.0641 Na 0.07 - 3.73 0 0.07 P <0.003 0.006 20 <0.003 Si 0.27 - 0.48 3 0.27 Zn <0.002 0.008 15 0.003 SO4 37 - 87 1 37 F - - Not Analyzed Chloride - - Not Analyzed Ca 15.8 31.4 2 15.8 NO3 - - Not Analyzed Acidity <2 7 1 <2 Alkalinity 3 12 1 0 2 Hardness I - - Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.58 7.45 1 1 6.7 EC 1 94 207 1 1 1 98 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 25 Weeks) 20-350-ABA12(Amphibolite) HC.11 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 25) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 1.2 - 2.2 15 1.6 Elem.An.2.2 µg/g B <2 4 2 <2 Ba 0.15 0.49 15 0.17 Be <0.007 0.008 2 <0.007 Bi <0.01 N/A <0.01 Cd <0.003 - 0.007 0 0.004 Co 0.044 - 0.108 0 0.086 Cr <0.08 0.15 2 <0.08 Cu <0.2 1.5 0 0.2 Mo 0.08 4.62 3 0.16 Ni 0.1 0.6 0 0.1 Pb <0.09 0.11 20 <0.09 Sb <0.9 N/A <0.9 Se <0.04 - 0.13 0 <0.04 Sn <0.06 0.2 0 <0.06 Sr 5.69 15 1 7.97 Ti 0.05 3.12 0 0.05 Th <0.1 N/A <0.1 TI <0.005 - 0.011 2 <0.005 U 0.009 0.068 15 0.009 V 0.30 3.48 0 0.30 W 0.04 - 1.56 2 0.04 Y <0.02 N/A <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.028 - 0.12 0 0.028 Fe <0.007 0.04 0 <0.007 K 0.074 - 0.509 0 0.039 Li 0.0109 0.371 0 0.0109 Mg 0.141 - 0.377 20 0.207 Mn 0.00146 0.00315 3 0.00161 Na 0.05 6.22 0 0.05 P <0.003 0.023 20 <0.003 Si 0.21 - 0.52 0 0.21 Zn <0.002 0.003 10 <0.002 Detected only once SO4 3 13 18 9 F - - Not Analyzed Chloride - - Not Analyzed Ca 2.03 5.31 15 4.26 NO3 - - Not Analyzed Acidity <2 N/A <2 Alkalinity 3 - 16 0 6 Hardness Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.87 - 9.12 1 1 6.93 Exceeded 8.5 only in week 0 EC 1 23 52 1 0 1 27 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 25 Weeks) 21-408-ABA14 (Schist) HC.12 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 25) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 N/A <0.05 As 0.2 - 0.5 1 0.2 Elem.An.5.7 µg/g B <2 4 2&3 <2 Ba 0.28 0.67 20 0.28 Be <0.007 0.026 1 <0.007 Bi <0.01 - 0.01 0 <0.01 Detected only once Cd <0.003 0.022 2 0.007 Co 0.019 0.064 2 0.035 Cr <0.08 0.13 20 <0.08 Cu <0.2 0.8 0 <0.2 MO 0.19 22.4 3 0.19 Ni <0.1 0.7 5 <0.1 Pb <0.09 N/A <0.09 Sb <0.9 N/A <0.9 Se 0.06 - 0.28 0 0.07 Sn <0.06 0.28 0 <0.06 Sr 9.30 20.0 15 14.9 Ti 0.09 0.89 1 0.14 Th <0.1 - 0.2 1 <0.1 Detected only once TI <0.005 0.013 2 0.005 U 0.040 0.977 15 0.687 V 0.29 0.98 0 0.29 W 0.03 1.5 0 0.03 Y <0.02 N/A <0.02 Zr <2 N/A <2 (Units:mg/L) Al 0.031 - 0.094 0 0.031 Fe <0.007 - 0.011 2 <0.007 K 0.427 - 4.83 0 0.427 Li 0.0096 0.344 2 0.0096 Mg 0.215 0.528 10 0.243 Mn 0.00209 0.00555 15 0.00442 Na 0.03 5.26 0 0.03 P <0.003 0.012 0 <0.003 Si 0.28 0.43 3 0.28 Zn <0.002 - 0.007 15 <0.002 Detected only once SO4 10 21 13 17 F - - Not Analyzed Chloride - - Not Analyzed Ca 2.89 8.53 15 7.65 NO3 - - Not Analyzed Acidity <2 N/A <2 Alkalinity 4 - 21 1 1 1 5 Hardness Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 6.84 - 8.69 1 1 7.00 EC 1 37 69 1 0 1 48 Piedmont Lithium Attachment 3: Summary of 2021-2022 Humidity Cell (ASTM D5744-96[reapproved 2001])Leaching Results (Leached for 30 Weeks) 21-408-ABA9(Schist) HC.13 Leachate Final Week Concentration Week of Peak Concentration Parameter Range Concentration (Week 30) Comments (Units:µg/L) Hg <0.01 N/A <0.01 Ag <0.05 - 0.07 0 <0.05 Detected only in week 1 As <0.2 - 1.0 15 0.2 El.An: 20 µg/g B <2 5 3 <2 Ba 0.47 - 1.55 0 0.52 Be <0.007 N/A <0.007 Bi <0.01 N/A <0.01 Cd <0.003 - 0.007 2,5,15,&20 0.005 Co 0.139 0.561 0 0.505 Cr <0.08 0.6 0&5 <0.08 Cu <0.2 0.6 0&5 <0.2 Mo 0.10 4.13 25 0.13 Ni 0.5 5.2 0 4.2 Pb <0.09 0.16 1 <0.09 Sb <0.9 N/A <0.9 Se 0.08 - 1.09 0 0.08 Sn <0.06 0.29 0 <0.06 Sr 12.5 45.9 0 12.5 Ti <0.05 0.4 4 <0.05 Th <0.1 N/A <0.1 TI <0.005 - 0.015 0&2 <0.005 U 0.152 - 1.091 2 0.228 V 0.03 0.14 4&20 0.03 W <0.02 - 0.3 0 <0.02 y <0.02 0.03 0 <0.02 Detected only once Zr <2 N/A <2 (Units:mg/L) Al 0.009 - 0.055 3 0.009 Fe <0.007 N/A <0.007 K 0.729 - 8.00 0 0.729 Li 0.0115 0.123 0 0.0133 Mg 0.19 1.82 0 0.19 Mn 0.0128 0.0897 30 0.0897 Na 0.04 - 4.96 0 0.06 P <0.003 0.010 20 <0.003 Si 0.29 0.62 3 0.32 Zn <0.002 0.005 15 <0.002 SO4 31 - 68 0 35 F - - Not Analyzed Chloride - - Not Analyzed Ca 12.1 25.6 0 12.1 NO3 - - Not Analyzed Acidity <2 9 1 <2 Detectable in weeks 1 and 2 Alkalinity 2 - 20 0 3 Below 10 by week 1 Hardness Not Analyzed (Units:pH in Standard Units,EC in µS/cm) pH 1 6.79 7.62 1 1 6.95 EC 1 76 199 1 0 1 82 Page intentionally left blank. Piedmont Lithium Attachment 4: LEAF Test Results Re: V,Al, As and pH under "natural" leachate conditions (Note: The LEAF How-To Guide(May 2019)issued by the United States Environmental Protection Agency(US EPA)establishes that the various LEAF methods are not regulatory compliance tests, and should not be used as such. Instead, LEAF is intended to help provide information about various leaching scenarios so that adverse conditions can be avoided via implementation of mitigation strategies.) V Al As Concentration Concentration Concentration Sample ID and Description (µg/L) (µg/L) (µg/L) pH LEAFA PAG Composite 20 1.50 8.9 - 15 9.8 LEAF.2 non-PAG/PAG/Concentrator Tailings with By-Products 23 - 36 1.4 - 1.6 2.7 - 6.8 9.3-9.6 LEAF.3 PAG/Concentrator Tailings with By-Products 27 1.7 - 2.3 29 - 32 9.6 LEAF.4 Sample 1-Concentrator Tailings with By-Products 2.7 - 3.6 0.65 - 0.71 2.3 8.9 LEAFS non-PAG/Concentrator Tailings with By-Products 34 1.7 - 1.9 1.3 9.6 LEAF.6 Composite#1,#2,and#3(Waste Rock) 5.2 - 6.8 0.71 0.69J 8.7 LEAF.7 Concentrator Tailings without By-Products <0.78 - 0.95.1 0.75 0.92.1 9.0 Piedmont Lithium Attachment 5: Duration of Elevated pH Relative to Regulatory Standards in Humidity Cell Tests Test Week in Week in Sample Duration pH which pH which pH Material ID (weeks) Range falls below 9 falls below 8.5 Note 2017-2018 Waste Rock Waste Rock 205-7 20 6.98 - 8.01 N/A N/A 2017-2018 Waste Rock Waste Rock 212-6 20 7.07 - 7.77 N/A N/A Concentrator Tailings Tailings 4 20 6.34 - 7.27 N/A N/A Schist 20-350-ABA8 20 6.91 - 8.32 N/A N/A Schist 21-408-ABA5 20 6.86 - 7.96 N/A N/A Schist 20-350-ABA6 25 6.58 - 7.45 N/A N/A Schist 21-408-ABA14 25 6.84 - 8.69 N/A Week 1 Was 8.69 in Week 0;8.45 in Week 1 Schist 21-408-ABA9 30 6.79 - 7.62 N/A N/A Mudstone 20-363-ABA6 20 6.86 - 7.88 N/A N/A Mudstone 21-408-ABA13 20 7.18 - 8.97 N/A Week 1 Was 8.97 in Week 0;8.42 in Week 1 Amphibolite 21-408-ABA6 20 6.50 - 7.71 N/A N/A Amphibolite 21-408-ABA11 20 7.33 - 8.95 N/A Week 1 Was 8.95 in Week 0;7.83 in Week 1 Amphibolite 20-350-ABA12 25 6.87 - 9.12 Week 1 Week 1 Was 9.2 in Week 0; 8.22 in Week 1 Piedmont Lithium Attachment 6: Humidity Cell Test Results Re:V,Al, and pH Test V Week Al pH when Week when Sample Duration pH (µg/L) pH when when (mg/L) Al>0.3 Al>0.3 Material ID (weeks) Range Range V>7 µg/L V>7 µg/L Range mg/L mg/L 2017-2018 Waste Rock Waste Rock 205-7 20 6.98 8.01 0.30 1.99 N/A N/A 0.057 0.111 N/A N/A 2017-2018 Waste Rock Waste Rock 212-6 20 7.07 7.77 0.14 0.59 N/A N/A 0.059 0.094 N/A N/A Concentrator Tailings Tailings 4 20 6.34 7.27 0.16 0.47 N/A N/A 0.007 0.55 7.21 1 Schist 20-350-ABA8 20 6.91 8.32 0.52 0.71 N/A N/A 0.029 0.065 N/A N/A Schist 21-408-ABA5 20 6.86 7.96 0.13 0.33 N/A N/A 0.025 0.066 N/A N/A Schist 20-350-ABA6 25 6.58 7.45 <0.01 0.08 N/A N/A 0.008 0.038 N/A N/A Schist 21-408-ABA14 25 6.84 8.69 0.29 0.98 N/A N/A 0.031 0.094 N/A N/A Schist 21-408-ABA9 30 6.79 7.62 0.03 0.14 N/A N/A 0.009 0.055 N/A N/A Mudstone 20-363-ABA6 20 6.86 7.88 0.47 1.3 N/A N/A 0.018 0.085 N/A N/A Mudstone 21-408-ABA13 20 7.18 8.97 0.7 1.64 N/A N/A 0.027 0.063 N/A N/A Amphibolite 21-408-ABA6 20 6.50 7.71 0.39 0.58 N/A N/A 0.027 0.052 N/A N/A Amphibolite 21-408-ABA11 20 7.33 8.95 1.28 2.05 N/A N/A 0.036 0.107 N/A N/A Amphibolite 20-350-ABA12 25 6.87 9.12 0.30 3.48 N/A N/A 0.028 0.12 N/A N/A Page intentionally left blank. Piedmont Lithium Attachment 7: Summary of Elevated Parameters in Humidity Cell Test Results Sample Duration of Elevated Standard Material ID Parameter Concentration Exceeded Comment 2017-2018 Waste Rock 2 Samples, No Instances of Elevated Parameters Concentrator Tailings 1 Sample, No Instances of Elevated Parameters Schist 20-350-ABA8 None 21-408-ABA5 None 20-350-ABA6 Co Week 0-1 and 10-25 NCGW 21-408-ABA14 pH Week 0 NCGW Week 0 pH =8.69 21-408-ABA9 None Mudstone 20-363-ABA6 None 21-408-ABA13 As Week 1-20(duration) DW, NCGW Sb Week 2 NCGW Detected only once pH Week 0 NCGW Week 0 pH =8.97 Amphibolite 21-408-ABA6 None 21-408-ABA11 JpH I Week 0 NCGW Week 0 pH =8.95 20-350-ABA12 JpH I Week 0 NCGW ]Week 0 pH =9.12 Notes RE: Humidity Cell Test Results >V: while indicated to be a potential COPC in LEAF M.1313 tests as a result of highly-elevated pH,V in Humidity Cells shows no exceedences of a standard at any time. >Al: while indicated to be a potential COPC in LEAF M.1313 tests as a result of highly-elevated pH,Al in Humidity Cells shows no exceedences of a standard at any time. >As: can exceed the DW standard and NCGW standard for extended periods in the mudstone. >Co: exceeded the NCGW standard in only one sample(a schist),and did so fairly persistently but at only low-level exceedences. >pH: slightly exceeded a standard in 4 of 13 samples, but quickly declined to within standards. Page intentionally left blank. Exhibits HkLLNNLLER Page intentionally left blank. P I E DAAO N T Stream and Wetlands LITHIUM Conceptual Reclamation Flow Diagram Onsite Lithium Treatment Hydroxide Product Pit Discharge t Ponds Offsite Waste Water Water Treatment Facility Pit Discharge Ponds Conversion Plant Active Open Pit Ore Ore Conversion Plant Tailings Concentrator Plant Concentrator Tailings Plant Water Waste Rock Disposal Facility ZAbove-ground Waste Rock Waste Rock Disposal Area I 7 Water I Fully Excavated Concentrator Plant Tailings Open Pit (to be backfilled) Sediment Control Ponds o Monitoring Point Stream and Wetlands Exhibit 1 Page intentionally left blank. CONCEPTUAL DIAGRAM OF WATER COLLECTION AND MONITORING SYSTEM IN BACKFILLED PIT WATER COLLECTION AND MONITORING SYSTEM ORIGINAL (DESIGN TBD) ORIGINAL GROUND GROUND COMPLETED PIT Q �BACKFILL ROCK ROCK O O WATER COLLECTION AND WATER COLLECTION AND MONITORING SYSTEM MONITORING SYSTEM (DESIGN TBD) ORIGINAL (DESIGN TBD) ORIGINAL GROUND GROUND AB VE-GROUNDi ♦Y WASTE ♦1 iiFtt♦ C PI iii ? �BACKFILLBACKFILL� ROCK ROCK? O O WATER COLLECTION AND MONITORING SYSTEM (DESIGN TBD) ORIGINAL TEMPORARYABOVE-GROUND GROUND TREATMENT ��.♦ BR WATT LE *IF NECESSARY, WATER COLLECTION AND MONITORING ¢ SYSTEM CAN BE PUMPED TO CREATE"REVERSE BACKFILL GRADIENT"CONDITIONS TO TEMPORARILY FACILITATE pH MITIGATION CONTROL. Y ROCKY , O Exhibit 2 Page intentionally left blank.