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Home My WebLink AboutNC0003468_11. DRSS CAP Part 2_Appx H_FINAL_20160210 Appendix H Monitored Natural Attenuation Technical Memorandum This page intentionally left blank Technical Memorandum To Mark Filardi / HDR Engineering, Inc. From Gregory P. Miller Date October 13, 2015 Subject Dan River Steam Station Corrective Action Plan Monitored Natural Attenuation – Tier I and II This technical memorandum presents the Tier I and Tier II evaluation of the attenuation of compounds dissolved in groundwater at the Dan River Steam Station (DRSS), Eden County, North Carolina. The memorandum consists of three sections: Background on Monitored Natural Attenuation (MNA) as a remedial alternative for coal combustion products; the Findings of the Tier I MNA Demonstration activity, followed by the Findings of the Tier II Demonstration. Investigative and data evaluation efforts are in progress as of the date of this memorandum. The findings herein represent the understanding as of this date and are subject to revision as new information becomes available. BACKGROUND Introduction to Monitored Natural Attenuation for Groundwater MNA is a strategy and a set of procedures used to demonstrate that physiochemical and/or biological processes in an aquifer will reduce concentrations of undesirable substances to levels below regulatory concern. It has been broadly applied to releases of petroleum hydrocarbons in many hydrogeological environments. There has been less application of MNA to the remediation of inorganic or radiologic substances in groundwater than to organic compounds. While MNA of organic contaminants is a readily accepted remedy at the State and Federal level, inorganic attenuation is more complicated and there is limited implementation experience in industry, science, and government. Metals, radionuclides, and/or other inorganic compounds are found in all aquifers. The mechanisms that regulate their release from solids and movement through aquifers are for the most part the same processes that control movement of inorganics in aquifers impacted by Coal Combustion Products (CCP) Leachate. These processes attenuate the concentration of inorganics in groundwater by depositing inorganics on aquifer solids. Unlike organic compounds that break down from hydrolysis or bacterial action, a reduction in concentration of dissolved inorganic compounds requires water to be removed from the aquifer, or the compounds immobilized by conversion to, or adsorption onto, solids. When demonstrated that the mechanism and permanence of natural processes will result in attenuation of undesirable compounds to acceptable levels, then remediation can be conducted by verifying that the remediation proceeds as predicted. MNA relies on natural processes to remove contaminants of concern from groundwater resulting in lower cost, and less disturbance of ground and infrastructure. Active remediation of inorganic compounds in the subsurface may rely on processes that are similar to or the same as natural attenuation mechanisms. Active remediation often seeks to improve or hasten these natural processes through chemical or biological augmentation of the aquifer. There are no clear distinctions between the late phases of conventional groundwater Geochemical, LLC PO Box 1468 Socorro, NM 87801 USA (575) 838-0505 www.geochemical.com M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 2 of 25 remediation and MNA, but such distinctions may be unnecessary. Relying on limited or low- energy active remediation as a preliminary step, then achieving final remedial goals through MNA is sometimes called “enhanced MNA”, or “enhanced attenuation.” Active remediation methods for petroleum products often leave residual dissolved contamination that is degraded slowly, requiring monitoring under regulations allowing MNA. Enhanced MNA is a common strategy in hydrocarbon remediation and the principle is adaptable to inorganic MNA. Authorizing Statutes MNA is a federally recognized remedial technology that can meet Resource Conservation and Recovery Act (RCRA) Corrective Action requirements and could be included when remedial alternatives for legacy CCP management sites are evaluated. Implementation of MNA for inorganics at RCRA facilities is clearly and favorably proposed by the United States Environmental Protection Agency (EPA) in the 1999 Office of Solid Waste and Emergency Response (OSWER) Directive 9200.4-7P. In that directive MNA is defined as: “the reliance on natural attenuation processes (within the context of a carefully controlled and monitored site cleanup approach) to achieve site-specific remediation objectives within a time frame that is reasonable compared to that offered by other more active methods. The ‘natural attenuation processes’ that are at work in such a remediation approach include a variety of physical, chemical, or biological processes that, under favorable conditions, act without human intervention to reduce the mass, toxicity, mobility, volume, or concentration of contaminants in soil or groundwater. These in-situ processes include biodegradation; dispersion; dilution; sorption; volatilization; radioactive decay; and chemical or biological stabilization, transformation, or destruction of contaminants.” Site characterization and assessment of MNA is different for organic and inorganic strategies. The focus in organic MNA is on a working understanding of the transformation rates and daughter products when organic chemicals break down in aquifers. Complex organic compounds are reduced to water, carbon dioxide, methane, and salts by biotic and abiotic processes in organic MNA. The science and engineering looks to the dissolved phase concentrations derived from groundwater samples. From those analytical results and aquifer dimensions and flow rates, the mass and flux of organic contaminants is evaluated over time. Meeting a single objective, mass reduction of organic compounds, is all that is needed to validate the organic MNA remedial approach. For inorganic contaminants, the scientific and engineering investigations must consider both the dissolved and solid phase. This is because inorganic compounds are not destroyed (with the exception of some radioactive decay chains), but become comingled with the aquifer solids. Inorganic compounds that are removed from the dissolved phase are transferred to the aquifer solids in inorganic MNA processes. The undesirable inorganic compound is not destroyed; its location is changed, from dissolved and mobile to immobile via incorporation into/onto a solid. Because inorganics are left in place, there is stakeholder concern about the stability and longevity of the remedial action. It is partly this uncertainty regarding inorganic MNA that drives the need for more in-depth study. While much of the chemistry is abiotic, biotic reactions can be very important in some inorganic MNA pathways. Inorganic MNA has two focus points: 1. Demonstrate that the attenuation process is reducing contaminant mass in groundwater; and, 2. Demonstrate that the remediation will meet long-term stability criteria without intervention. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 3 of 25 Principles of Inorganic Attenuation The 1999 OSWER Directive provides limited policy and implementation guidance for inorganic MNA. EPA indicates that: the site-specific mechanisms of attenuation of inorganic contaminants should be known; and, the stability of the remedial action should be evaluated under potential changes in conditions. The OSWER Directive is fairly specific about the classes of attenuation processes that may be proven effective, stating: “MNA may, under certain conditions (e.g., through sorption or oxidation-reduction reactions), effectively reduce the dissolved concentrations and/or toxic forms of inorganic contaminants in groundwater and soil. Both metals and non-metals (including radionuclides) may be attenuated by sorption reactions such as precipitation, adsorption on the surfaces of soil minerals, absorption into the matrix of soil minerals, or partitioning into organic matter.” “Oxidation-reduction (redox) reactions can transform the valence states of some inorganic contaminants to less soluble and thus less mobile forms (e.g., hexavalent uranium to tetravalent uranium) and/or to less toxic forms (e.g., hexavalent chromium to trivalent chromium). Sorption and redox reactions are the dominant mechanisms responsible for the reduction of mobility, toxicity, or bioavailability of inorganic contaminants.” “It is necessary to know what specific mechanism (type of sorption or redox reaction) is responsible for the attenuation of inorganics so that the stability of the mechanism can be evaluated. For example, precipitation reactions and absorption into a soil’s solid structure (e.g., cesium into specific clay minerals) are generally stable, whereas surface adsorption (e.g., uranium on iron-oxide minerals) and organic partitioning (complexation reactions) are more reversible.” “Complexation of metals or radionuclides with carrier (chelating) agents (e.g., trivalent chromium with EDTA) may increase their concentrations in water and thus enhance their mobility. Changes in a contaminant’s concentration, pH, redox potential, and chemical speciation may reduce a contaminant’s stability at a site and release it into the environment. Determining the existence, and demonstrating the irreversibility, of these mechanisms is important to show that a MNA remedy is sufficiently protective.” “Inorganic contaminants persist in the subsurface because, except for radioactive decay, they are not degraded by the other natural attenuation processes. Often, however, they may exist in forms that have low mobility, toxicity, or bioavailability such that they pose a relatively low level of risk. Therefore, natural attenuation of inorganic contaminants is most applicable to sites where immobilization or radioactive decay is demonstrated to be in effect and the process/mechanism is irreversible.” There have been numerous advances in the understanding of the environmental geochemistry of inorganic compounds and metals since publication of the Directive in 1999. The inorganic MNA topics discussed in the Directive are still valid, and form a first step to evaluate inorganic MNA. Over the period of 2006−2010 EPA has released much more detailed guidance on implementation of inorganic MNA and the Interstate Technical and Regulatory Council (ITRC) has published on practical and regulatory aspects of implementing MNA inorganic at the state regulatory level. These guidance documents are summarized in a following section. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 4 of 25 Governing Equations The concentration of a dissolved compound in flowing groundwater changes over time due to movement, mixing, and chemical reactions. The concentration of COIs in DRSS groundwater is governed by these same processes. At DRSS, groundwater movement and mixing probably changes COI concentrations as much or more than chemical reactions do. Following source control, COI concentrations in DRSS groundwater will decrease due to the combination of these processes, resulting in COI concentration attenuation. The change in COI concentration with respect to time and place can be described by the advection-dispersion equation (ADE). The ADE is used to determine the concentration of COI in groundwater during remedial scenarios − including MNA. In differential form, including reversible and irreversible sorption to solids, the ADE is: Ct S x Cvx CDt C b µδ δ θ ρ −−∂ ∂−∂ ∂=∂ ∂ 2 2 where: C = concentration of solute in water t = time x = distance from source D = Dispersivity v = average groundwater velocity ρb = solid bulk density ϴ = solid porosity S = concentration of solute on solid µ = rate of solute irreversible sorption The first and second terms in the ADE describe the change in COI concentration due to mixing and diffusion in granular aquifers (D − Dispersivity), and the change in concentration from groundwater flow moving the solute away from the point of interest (v − average groundwater velocity), respectively. The third term in the ADE, related to concentration of solutes on solids and reversible sorption processes, has alternate formulations that are very useful in solute fate and transport modeling. The relationship between the concentrations of reversibly adsorbed solutes on solids and the dissolved concentration in groundwater can be stated as a proportionality – Kd, where: 𝐾𝐾𝑑𝑑=𝑆𝑆𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶𝐶 where: SB is for the concentration of COI on solids, and CB is for the concentration of COI in the water, when COI chemistry is at equilibrium. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 5 of 25 Kd is a proportionality of concentration between the solids and the liquids in an aquifer. It commonly has units of volume over mass. In order to use Kd in the ADE formulation it is often expressed as Retardation – R, where: 𝑅𝑅=1 +𝜌𝜌𝜃𝜃𝐾𝐾𝑑𝑑 In the Retardation equation, we see the reappearance of bulk density and porosity from the ADE with the surface concentration term contained in the proportionality Kd. The effect of R and D on solute transport time and concentration can be seen from the figure below for model transport of retarded and non-retarded solutes with equal Dispersivity. Note that in the retarded case ‘a’ that velocity is divided by Retardation; an R value of 1 indicates no retardation. Retardation and Dispersivity are conservative with respect to solute mass. If COI has a high Kd, it will have a high R. A high R puts higher contaminant mass on the solids in proportion to the amount dissolved in water. When the water concentrations decrease to background over time, the solids will release COIs until that mass was exhausted to background concentrations. If R is low, that return to background concentrations on solids will happen relatively quickly. The final term in the ADE is related to irreversible sorption processes. To describe the attenuation of COI at DRSS, the inputs to the ADE are satisfied as follows: ADE Variable Data Source C Concentration measured from groundwater samples. t Time is determined by the nature of the problem to be investigated, e.g., the time for COI in groundwater to fall below the 2L Standard. x Distance is determined by the nature of the problem to be investigated. D Dispersivity is estimated from published values or determined from solute concentrations over time using numerical models. v Average groundwater velocity varies in space and time and is supplied by a calibrated groundwater flow model. ρb Bulk density measured from samples. ϴ Porosity measured from samples. S Concentration measured from solid samples. Calculated Kd values from laboratory batch and column testing. µ Irreversible component of S. Not determined at this time. 0 1 C/ C o Increasing Distance → D and R D Only a b tvxb=  + = d a K tvx θ ρ1 M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 6 of 25 Kd Calculations and Interpretation There are many different mathematical models to describe sorption, Kd, Langmuir Isotherms, and Freundlich Isotherms are common methods (USEPA, 1999). All of the models have advantages and limitations. If you know the solution concentration, and can model or measure the solid concentration, you can calculate Kd. If confidence in the model is high, the solution concentration can be assumed and surface concentrations of COI calculated directly (Goldberg et al., 2000; Dzomback and Morel, 1990). One limitation to the Kd approach is that it does not describe the effect of variable pH conditions. The question of pH is important on many levels. We know that COI will take on an electrical charge based on pH, that the surfaces of minerals that adsorb COI are variably charged, again dependent on pH, and that the propensity of COI to approach a surface depends on all of these charges. To handle these complexities, surface complexation theory was developed (Dzomback and Morel, 1990). Surface complexation theory states that we can describe these sorption reactions the same way as we describe chemical reactions, as mass-action equations that have equilibrium constants. K’s are numerical constants for chemical mass-action equations. They express the equilibrium relationships between chemicals. Setting an equilibrium chemical reaction with A and B as reactants, C and D as products, where the variable is concentration: DCBA+=+, the mass-action equation takes the form: BA DCK=. K is constant at constant temperature and pressure. Three constants are needed to model the surface complexation approach, one for the COI adsorption to the surface and two to describe the charging of the surface. The surface charging constants K- and K+ are determined for pH- dependent protonation-deprotonation reactions at the oxide surface. The protonation reactions with the surface, SOH, are described by the two-step reversible process below. The mass-action relationship for COI (KCOI) can be expressed in a generic form as: +−+⇔+HCOISHCOIHSOHyxyx [][] [][]() ()RT F COIHSOH HCOISH COI yx yxK 0expψ−+−=, where square brackets indicate concentrations (mol/L), F is the Faraday constant (C/mol), Ψ is the surface potential (V), R is the molar gas constant (J/mol K), T is the absolute temperature (K), and the exponential terms represent solid-phase activity coefficients that correct for charges [] [][] () ()RT F HSOH SOH sK 02exp ψ + +=+ [][] [] () ()RT F SOH HSO sK 0exp ψ− − +−= ++⇔+2SOHHSOH SOHHSO⇔++− M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 7 of 25 on the surface complexes. Each KCOI mass-action expression must be constructed from a balanced equation using the generic form above as an example. Mass-action constants can be determined from adsorption experiments (Kd determinations) using the code FITEQL (Herbelin and Westall, 1999) and several surface complexation sub-models are available in PHREEQC. Irreversible Sorption of COIs Irreversible sorption of COIs has been observed in/on a range of geomedia for over 100 years. Here the irreversible sorption for COIs is defined as: COIs that are retained in the structure of minerals and mineral-like inorganic and organic compounds on a time scale significantly longer than reversible surface adsorption reactions. In most cases, reversible surface sorption reactions are instantaneous as compared to groundwater flow rates. Irreversible sorption processes for COIs are common in the natural environment. COIs will be taken up to form part of the mineral lattice of clay minerals, hydrous metal oxides, carbonates, and composted organic material, as examples. Clay minerals and hydrous metal oxides are common at the site. Release of COI from these materials is slow. The chemical equilibrium between solutions and solids is a balance between the rate of forward reactions and the rate of back reactions. Surface complexation adsorption processes are reversible equilibrium reactions. Irreversible sorption is a process where the forward reaction is so much faster than the back reaction that the reverse reaction is insignificant on the time scale of interest. The remobilization mechanism is too slow to be significant. Irreversible sorption is a COI sink; COI is removed from the flow system. First-order decay is one way to represent irreversible sorption in a numerical model. First-order decay rates are also used to calculate the half-life of a compound. Inverse Modeling of Hydrologic Parameters Determination of most of the physical properties that effect solute transport in granular aquifers can be accomplished using laboratory or field tracer tests. Dispersivity, retardation, and effective porosity can be quantified this way. These are important parameters for modeling of solute transport in groundwater. Laboratory and field tracer tests are controlled experiments often involving forward modeling of expected conditions to constrain the experimental design. Determining the appropriate concentration of tracer to be used and how long to apply it to have a successful experiment (source term) would be an example of forward modeling. Inverse modeling is fitting of aquifer parameters to observed concentration/distance/time data. Laboratory and field breakthrough curves (BTCs) generally trace smooth curves due to frequent sampling and the ability to rerun experiments. Data from groundwater monitoring programs can be used for determination of aquifer parameters in the same manner as laboratory tests, if the data provide a fairly complete record of changes in concentration of a dissolved solute. Ideally, monitoring would be frequent and the rising limb and falling tail of the solute BTC would be captured with accuracy and precision. Forward modeling of field conditions is possible if the source term is known or assumed. BTC data from groundwater monitoring generally has an imperfect understanding of the concentration (C) and duration (t) of the contaminant source over time – the source term. The distance between the source (z) and the monitored well may also be hard to quantify. A public-domain program for numerical evaluation of BTCs is available. CXTFIT, Version 2.1 (Toride et al., 1999), is useful for determining values for average linear velocity (v), dispersivity (D), retardation (R), and decay (µ), which is used to account for irreversible adsorption. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 8 of 25 Independent data for v are available from the calibrated flow model, tests of hydraulic conductivity, and measurement of gradients. Similarly, R has been determined independently from laboratory measurements of bulk density (ρb), effective porosity (n), and partition coefficients (Kd). Laboratory or field determined values for dispersivity (D) or decay (µ) are not available at this time. Coal Combustion Product Leachate Characteristics Inorganic MNA relies on being able to observe, quantify, and in some cases modify subsurface chemistry. There are major differences in the chemical characteristics of leachate across the major groups of CCP (fly ash, bottom ash, pollution control residue), and complexities introduced by co-disposal of different CCPs. The composition of leachate from CCP is highly variable. Controls on leachate chemistry are numerous and are strongly influenced by site- specific factors. Leachate chemistry is influenced to variable and unequal degrees by: • The type of coal; • The basin, sub basin, mine, or seam it is produced from; • Variability of coal composition within the seam; • Coal cleaning and pretreatment processes; • Combustion conditions; • Pollution control operations; • CCP handling; • CCP management strategies – impoundments, landfills or combined methods; and, • Climate and environmental factors – such as hydrology, geology, and weather. The preceding list of factors, that ultimately control the success of inorganic MNA, is imperfect and not meant to be exhaustive. There is a large knowledge base on the geochemistry of CCP and CCP leachate. That information is very helpful to constrain remedial strategies for legacy CCP sites, but does not replace the detailed site-specific assessment of ash and aquifer geochemistry required for inorganic MNA. The Electric Power Research Institute (EPRI) has conducted extensive research on the occurrence, concentration, and mobility of CCP leachate components. The selection criteria EPRI used to identify constituents of concern (COCs) included prevalence, mobility, and risk as determined by comparison to water quality standards. EPRI’s assessment identifies five leachate constituents that are probably present in pore water at all legacy CCP management sites; arsenic, boron, chromium, selenium, and sulfate. Each of these substances has triggered at least one remedial action at a legacy CCP site. While these constituents are the primary focus of concern due to their prevalence and mobility, several other inorganic constituents may be of concern at legacy CCP management sites. From EPRI’s 2006 effort, the following constituents are noted: “The leachate data indicate that concentrations of antimony, arsenic, cadmium, chromium, selenium, and thallium were higher than health-based MCLs in at least 10 percent of the samples. In addition, the 90th percentile concentrations of boron, lithium, manganese, molybdenum, sodium, sulfate, and vanadium were higher than alternative drinking water criteria. These constituents are more likely to trigger a remedial action in the event of a leachate release than constituents that typically have leachate concentrations lower than drinking water standards.” M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 9 of 25 The EPRI-listed constituents above are primary candidates for MNA because of their occurrence, mobility, and propensity to exceed drinking water standards at legacy CCP sites. Not all of these constituents are amenable to remediation through MNA processes because of their chemical properties. Table 1 compares the leachate chemistry as identified by the previously listed EPA and EPRI sources, with the compounds suitable for inorganic MNA as found in the EPA, EPRI, and ITRC guidance documents. The EPA sources cited identify the following thirteen COCs based on the potential for human health and/or ecological impacts using a screening risk assessment: aluminum, arsenic, antimony, barium, boron, cadmium, cobalt, chromium, lead, mercury, molybdenum, selenium, and thallium. One of the findings of the 2009 EPA report was nine of the thirteen COCs listed above were found in CCP leachate at levels of concern for groundwater protection, as indicated in Table 1. Published Guidance on Inorganic Monitored Natural Attenuation United States Environmental Protection Agency Guidance The EPA is the primary source of guidance on MNA. The EPA has published their inorganic MNA guidance in three volumes. Volume 1 is a procedural and technical guide for implementing MNA; Volume 2 is a detailed exploration of issues associated with inorganic MNA for nine compounds; and Volume 3 contains discussion of MNA issues unique to radionuclides and a detailed exploration of inorganic MNA for ten radionuclides. Volumes 1 and 2 were published in 2006 and Volume 3 in 2010. The EPA guidance documents cover inorganic MNA at a high level of scientific detail. The EPA guidance, while not specific to CCP, is a technical resource on evaluation of the feasibility of inorganic MNA for compounds as listed in Table 1. Volume 1 introduces EPA’s “Tiered Analysis Approach to Site Characterization”; the tiers being four demonstrations or findings to be accomplished when implementing inorganic MNA. Volume 1 provides specific technical guidance on implementing inorganic MNA using the four- tiered approach. Volume 2 expands on the technical guidance to include specific strategies and chemical mechanisms for arsenic, cadmium, chromium, copper, lead, nickel, nitrate, perchlorate, and selenium inorganic MNA. Volume 3 presents the evaluation of MNA for radionuclides. Table 2 presents a simplification of the four-tiered approach found in the EPA guidance. CCP inorganic MNA is not considered by EPA to be a viable remedial alternative for groundwater unless the leachate additions to groundwater have been controlled. Developing a site-specific understanding of the mechanism by which inorganic MNA may attenuate (Tier II) and the capacity of the aquifer to do so (Tier III) is a complex and iterative task. Volume 1 provides the technical basis for inorganic MNA evaluations to accomplish Tier II and III goals. Monitoring of inorganic MNA is necessarily more detailed than for many active remediation strategies and is discussed in Volume 1. Interstate Technology Research Council Guidance In late 2010, ITRC published a decision framework for inorganic MNA. The document contains a summary of the three-volume EPA guidance, expanded to decision framework for determining MNA feasibility. Case studies are included and compared to the EPA four tiered approach. The MNA implementation at the state level was surveyed and reported. The ITRC document summarizes the topic of inorganic MNA, presents an introduction to the science, and presents a strategy for training and implementation of inorganic MNA under state laws and regulations. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 10 of 25 This guidance is not specific to CCP. As with the EPA guidance, it is a technical resource on evaluation of the feasibility of inorganic MNA for compounds in Table 1. Table 1. Compounds in CCP leachate as compared to MNA guidance. EPA CCP EPRI CCP EPA MNA ITRC MNA EPRI MNA Aluminum (Al) X XX Antimony (Sb) XX XX Arsenic (As) XXX XXX X X X Barium (Ba) XXX X Beryllium (Be) X X Boron (B) XX XXX X Cadmium (Cd) XX XX X X Calcium (Ca) X X Chromium (Cr) XXX XXX X X X Cobalt (Co) X X X Copper (Cu) X X X Fluorine (F) X X Iron (Fe) X X Lithium (Li) XX Lead (Pb) X X X X Magnesium (Mg) X Manganese (Mn) X XX Mercury (Hg) X X Molybdenum (Mo) XX XX Nickel (Ni) X X X X Potassium X X Selenium (Se) XXX XXX X Silicon (Si) X Silver (Ag) X X Sodium (Na) X X Strontium (Sr) X X Thallium (Th) XX XX Vanadium (V) X XX Zinc (Zn) X X X pH X X Sulfate (SO4) X XXX X Dissolved Solids X XX Radionuclides X X EPA CCP: X=mentioned, XX= of concern, XXX=exceeds toxicity criteria EPRI CCP: X= evaluated, XX= of concern, XXX=of concern and common Table 2. Summary of USEPA four-tiered feasibility evaluation for inorganic MNA. Tier I Source Control Is the contaminant mass in the plume decreasing? Tier II Attenuation Mechanism Is the chemical mechanism well understood? Tier III Attenuation Capacity Is the capacity and permanence of the mechanism sufficient? Tier IV Monitoring & Contingency How will monitoring be conducted? What actions will be taken if monitoring indicates attenuation is lacking? M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 11 of 25 TIER I DEMONSTRATION FOR THE DAN RIVER STEAM STATION MNA is a candidate remedial technology for Constituents of Interest (COIs) exceeding 2L Standards in groundwater at the DRSS. Attenuation processes reduce the concentration or toxicity of compounds in groundwater primarily by chemical interaction with aquifer solids. When attenuation processes result in a reduction of contaminant concentrations in a timeframe similar to other remedial technologies, attenuation can be an acceptable remedial alternative (USEPA, 2007). This section documents that the first milestone in the Four-tiered MNA process has been achieved; attenuation of certain COIs has been observed. This successful Tier I demonstration is based on the methods contained in EPA guidance (USEPA, 2007). The MNA demonstration for certain COIs will now be advanced to Tier II/III. A work plan for MNA evaluation was submitted, reviewed, revised and approved by the North Carolina Department of Environment and Environment Resources (DENR). All proposed activities were accomplished with minor deviations from the plan. Data were collected on the distribution of COIs in groundwater, porewater, and soil in three dimensions to evaluate if attenuation was occurring. A strong, positive correlation between COI concentration in water and solid pairs indicates attenuation (USEPA, 2007) and is the first step (Tier I) in evaluation of MNA as a remedial technology. EPA guidance defines Tier I (USEPA, 2007, page 6) as: “Demonstration that the ground-water plume is not expanding and that sorption of the contaminant onto aquifer solids is occurring where immobilization is the predominant attenuation process.” Determination of plume stability or non-expansion generally follows source control. Quantitative analysis of plume stability assuming source control was conducted as part of the numerical modeling effort supporting the CAP. Fate and transport modeling used the site-specific partitioning coefficients developed as part of a laboratory testing program to determine site- specific attenuation capacities (Kd) for COIs at DRSS. Tier I objectives were accomplished by chemical evaluation of collocated aquifer solids and groundwater (i.e., solid/water pairs) as described in the EPA guidance (USEPA, 2007, page 6): “Determination of contaminant sorption onto aquifer solids could be supported through the collection of aquifer cores coincident with the locations of ground-water data collection and analysis of contaminant concentrations on the retrieved aquifer solids.” MNA requires additional testing and data interpretation beyond Tier I to allow reasonable comparison to other remedial alternatives with respect to efficacy, cost, stakeholder acceptance, and time to meet remedial goals. This will be accomplished for COIs by completing Tiers II and III of MNA Demonstration. The groundwater COI’s for DRSS are arsenic, boron, iron, manganese, sulfate, and TDS with localized 2L exceedances for antimony, chromium, cobalt, selenium, and thallium. Cobalt, iron, manganese, and vanadium occur naturally in regional groundwater. Sulfate and TDS are generally not attenuated by reactions with solids, but are reduced in concentration by diffusion, mechanical mixing, or dilution. Here we consider water-solid pairs and site-specific Kd data as evidence for attenuation for antimony, arsenic, boron, chromium, cobalt, selenium, and thallium. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 12 of 25 Water and solid chemistry data from the CSA, and previous sampling by Duke consultants, were used to conduct the Tier I analysis. A single extraction method was used on solids, USEPA SW-846 Method 3051A. When a water sample could be matched with more than one solid sample in the screened section of the well, multiple solid-water pairs were created. Non- detection (U values, below detection limit) were not used in the comparison or were substitute values used. J values (presence indicated, below quantification limit.) were used as reported. As reflected in Table 3, a total of 21 solid-water pairs were used for the DRSS Tier I Demonstration. Tier I Analysis Tier I analysis uses two lines of evidence for attenuation. Solid-water pair comparison of COI concentrations are performed, a mutually rising relationship indicating attenuation (EPA 2007); and, laboratory determination of the solid-water partitioning coefficient or Kd value (EPA 1999) is used as measure of the propensity of COIs to adsorb to site-specific solids and be attenuated. If a solid-water pair comparison chart is not presented, there was insufficient data for Tier I analysis for that element. Laboratory determination of Kd was performed by the University of North Carolina Charlotte (UNCC) under the supervision of Dr. William Langley on 12 site-specific samples of soil, or partially weathered rock (saprolite) from the transition zone (Table 4). Solid samples were batch equilibrated and/or tested in flow through columns to measure the adsorption of COIs at varying concentrations. These multiple data points for each COI and sample are evaluated to determine if the observed data can be fit to an adsorption isotherm. If fitting to an isotherm is supported, a Kd is calculated; blanks in Table 4 indicate that a reasonable isotherm was not observed in that test. Tests are conducted in duplicate or triplicate to evaluate error. Table 4 also presents calculated median batch-test Kd values for each COI averaged across all tests, the minimum and maximum values, and the ratio of the maximum to the minimum value as an indication of the variance in the results. The same information is presented for the column tests. There were 22 batch tests and 14 column tests conducted on Dan River samples. Column testing was not successful at producing isotherms for antimony, chromium, cobalt, iron, and manganese. Iron and manganese Kd determinations in batch or column were difficult due to the high concentrations of poorly crystalline iron and manganese oxides and oxyhydroxides present in the Piedmont soils and saprolite. Inspection of the comparison of batch and column tests in Table 4 reveals that column Kd values are significantly less than batch values with exception of boron and cadmium, where column Kd values are slightly higher for cadmium and approximately four times higher for boron. The variability in Kd measurement across the 12 samples is dependent on the COI. Kd values vary from thousands of ml/g to single digits. The variation in the ratios of maximum/minimum (max/min) Kd is not correlated to the calculated medians of Kd. We observe that the highest median Kd value (iron, Kd 3899, max/min 13.5) does not have a max/min ratio much greater than smallest Kd (boron, Kd 2.5, max/min 3.5) when compared to the observed max/min ratios of 1.7 (chromium) to 621.7 (manganese). Combined, this seems to indicate that we can use the max/min ratio as a subjective indicator of the potential for COI to have a Kd that is variable across geomedia. The relative strength in binding based on the batch Kd data is: Iron > Arsenic > Thallium > Cobalt > Selenium > Molybdenum > Vanadium > Cadmium > Antimony > Chromium > Manganese > Boron. The potential for a variable Kd across the site is in the order: Manganese > Molybdenum > Selenium > Antimony > Arsenic > Vanadium > Iron > Cobalt > Thallium > Cadmium > Boron > Chromium. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 13 of 25 Antimony Antimony attenuation using solid-water pairs was not observed. There were less than three data pairs, preventing analysis. The calculations of a median Kd of 120 ml/g for antimony indicated that it should be moderately to strongly attenuated at the site. The max/min ratio of 81.5 suggests that some variability in Kd across the site is to be expected. Natural attenuation of antimony should be observed and the COI should be carried through to Tier II. Arsenic From Table 3 the solid-water pair concentrations of arsenic are plotted in Figure 1. The rising concentrations in groundwater are matched by rising concentrations in solids, indicating that the solids are attenuating arsenic concentrations in groundwater. Kd determinations for arsenic support the solid-water pair observation with a calculated median Kd of 1416 ml/g. Variability in observed Kd should be moderate with a max/min ration of 31.1. Natural attenuation of arsenic has been observed, and the COI should be carried through to Tier II. Figure 1 Boron Figure 2 depicts the solid-water pair analysis for boron. Attenuation is not observed in this plot. Calculated site-specific boron Kd values are low (2.5 – 12 ml/g) but are consistent with Kd values observed for boron uptake in soils (Goldberg, 2000). Boron attenuation is often controlled by clay mineralogy. The large amounts of illite clay observed, boron’s favored sorption by illite, and observations of partitioning and attenuation in controlled laboratory conditions suggest that boron attenuation is taking place, albeit in smaller amounts than other COIs. The attenuation of boron has been observed and it should be carried through to a Tier II evaluation. 0 100 200 300 400 500 600 700 800 0 20 40 60 80 Ar s e n i c , d i s s o l v e d ( µ g / L ) Arsenic (mg/kg) M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 14 of 25 Figure 2 Chromium Figure 3 depicts the solid-water pair analysis for chromium. Attenuation is not observed in this plot. Calculated site-specific chromium Kd values are low (27 ml/g) but are not absent. It was difficult to fit isotherms for many samples. While Tier I identified limited evidence for attenuation, inclusion of chromium in initial Tier II analysis may reveal more certain observations. The attenuation of chromium is suggested by limited successful determinations of Kd on site-specific geomedia and chromium should be carried through to a Tier II evaluation based on limited potential. Figure 3 Cobalt Cobalt attenuation using solid-water pairs was not observed. There were less than three data pairs, which prevented analysis at this time. The calculations of a median Kd of 1041 ml/g for cobalt indicated that it should be strongly to very strongly attenuated at the site. The Max/Min ratio of 12.5 suggests that limited variation in Kd across the site is to be expected. Natural 0 200 400 600 800 1000 1200 1400 0 10 20 30 40 50 Bo r o n , d i s s o l v e d ( µ g / L ) Boron (mg/kg) 0 1 2 3 4 5 6 7 0 20 40 60 80 Ch r o m i u m , d i s s o l v e d ( µ g / L ) Chromium (mg/kg) M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 15 of 25 attenuation of cobalt should be observed and the COI should be carried through to Tier II on the basis of the high Kd value observations. Selenium Selenium attenuation using solid-water pairs was not observed. There were less than three data pairs, which prevented analysis at this time. The calculations of a median Kd of 624 ml/g for selenium (batch) and 125 ml/g in column tests indicated that it should be moderately to strongly attenuated at the site. The Max/Min ratio of 82.5 (26.7 column) suggests that moderate variation in Kd across the site is to be expected. Natural attenuation of selenium should be observed and the COI should be carried through to Tier II on the basis of the high Kd value observations in batch and column tests. Thallium Thallium attenuation using solid-water pairs was not observed. There were less than three data pairs, which prevented analysis at this time. The calculations of a median Kd of 1085 ml/g for thallium (batch) and 408 ml/g in column tests indicated that it should be moderately to very strongly attenuated at the site. The Max/Min ratio of 10.5 (13.6 column) suggests that little variation in Kd across the site is to be expected. Natural attenuation of thallium should be observed and the COI should be carried through to Tier II on the basis of the high Kd value observations in batch and column tests. Vanadium From Table 1 the solid-water pair concentrations of vanadium are plotted in Figure 4. The rising concentrations in groundwater are matched by rising concentrations in solids, indicating that the solids are attenuating vanadium concentrations in groundwater. The calculations of a median Kd of 425 ml/g for vanadium (batch) and 283 ml/g in column tests indicated that vanadium should be moderately to strongly attenuated at the site. The Max/Min ratio of 20.6 (31.7 column) suggests that little variation in Kd across the site is to be expected. Natural attenuation of vanadium should be observed and the COI should be carried through to Tier II on the basis of the high Kd values in batch and column tests. Figure 4 Tier I Findings Tier I analysis indicates that antimony, arsenic, boron, chromium, cobalt, selenium and thallium should be carried through to Tier II determinations of mechanism. Vanadium, although related 0 5 10 15 20 25 0 20 40 60 80 Va n a d i u m , d i s s o l v e d ( µ g / L ) Vanadium (mg/kg) M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 16 of 25 to background concentrations, should be carried through to Tier II to improve the understanding of its site-specific occurrence and mobility. TIER II DEMONSTRATION FOR THE DAN RIVER STEAM STATION MNA is a candidate remedial technology for the groundwater COIs originating on DRSS property. A strong positive correlation between COI concentrations in solid-water pairs indicates attenuation. Correlation was demonstrated as documented in the Tier I demonstration. This section covers Tier II demonstration of mechanism and rate for COI attenuation. Attenuation processes reduce the concentration or toxicity of compounds in groundwater primarily by advection, dispersion, and chemical interaction with aquifer solids. When attenuation processes result in a reduction of contaminant concentrations in a timeframe similar to other remedial technologies, attenuation can be an acceptable remedial alternative (USEPA, 2007). In completion, the Tier I, II, and III MNA demonstrations indicate that MNA is operable on a timescale comparable to active remedial technologies (e.g. pump and treat) that have been screened for the DRSS groundwater portion of the CAP. MNA is being considered in the CAP for DRSS groundwater as a remedial technology. A work plan for MNA evaluation was submitted, reviewed, revised and approved by DENR. All proposed activities were accomplished with minor deviations from the plan. Data were collected on the distribution of COI in groundwater and geomedia in three dimensions to evaluate if attenuation was occurring. The first use of the data was to evaluate the premise of COI attenuation (Tier I) using a subset of results from the approved data collection program. The groundwater COIs for DRSS are arsenic, boron, iron, manganese, sulfate, and TDS with localized 2L exceedance for antimony, chromium, cobalt, selenium and thallium. Tier I analysis indicates that antimony, arsenic, boron, chromium, cobalt, selenium and thallium should be carried through to Tier II determinations of mechanism. Vanadium, although related to background concentrations, should be carried through to Tier II to improve the understanding of its site-specific occurrence and mobility. The process was intended to be flexible based on findings (the observational approach) or in response to agency comments or new scientific opportunities that may arise. EPA guidance defines Tier II (USEPA, 2007, page 6) as; “Determination of the mechanism and rate of the attenuation process.” and, continues on page 7 with further clarification on rate: “The objective under Tier II analysis would be to eliminate sites where further analysis shows that attenuation rates are insufficient for attaining cleanup objectives established for the site within a timeframe that is reasonable compared to other remedial alternatives.” MNA tasks require an observational approach and the reliance on predictive models increases over the duration of the project (Tier I to III). The MNA demonstration process results in increasing levels of confidence in the reliability of MNA as a remedial solution. There are two technical paths that contribute to the same site conceptual model. There is a technical path primarily related to calculations and modeling of groundwater flow, contaminant transport, and how fate and transport of the COIs is affected by remedial alternatives, attenuation, or no action. Supporting those calculations are geochemical activities primarily related to technical evaluation of COI attenuation capacity, permanence, and remedial effectiveness over time. The technical M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 17 of 25 activities proposed for the CSA relied on our pre-Tier I best understanding of COI attenuation processes in DRSS groundwater and were subject to change based on observation, study objectives, or Tier goal attainment by alternate methods. Site Conceptual Model for Attenuation Lithologic Controls on Water Quality The USGS and NCDENR recently completed regional studies (USGS 2009, USGS 2013) of the chemical quality of groundwater in the Blue Ridge and Piedmont Provinces. DRSS is located in the Mesozoic Geozone of USGS 2009, a small province occupying only about five percent of the surface area of the Blue Ridge and Piedmont Provinces in NC. The Mesozoic Basin in the vicinity of the DRSS is composed of siliciclastic (high-quartz and feldspar arkose) sediments with significant intervals of fine-grained material (siltstones and mudstones). The carbonate rock type often found in Mesozoic basins is absent at DRSS. While waters from the siliciclastic aquifers have different water quality profiles from crystalline rock and carbonate aquifers, comparative data was not meaningful in that both aquifer types have overlapping water quality criteria. A notable consideration from the two recent USGS papers is that is it possible to roughly rank the potential for natural background occurrence of heavy metals (Sb, As, Ba, Co, Cr, V, and Zn as examples) by rock type as Mafic Crystalline > Felsic Crystalline > Siliciclastic > Carbonate > Recent Alluvium. Mafic material (igneous-origin rock that contains larger percentages of Fe and Mn silicates than quartz or feldspars) has a link to background levels of heavy metals at DRSS. Mafic minerals present in sedimentary units have the same connection. The Dan River surface geologic mapping indicates a diabase dike cross-cuts the property, which is a mafic rock unit that can contribute to observable trace metals in groundwater. Mineralogical Controls on Attenuation COIs are adsorbed to organic matter, oxide minerals, and clay minerals. These are the predominant sources and sinks for COIs in groundwater, soil, or sediment. All of these solids are present in subsurface materials at DRSS. COIs adsorbed on these solids equilibrates with solution COI concentrations. Some COIs adsorbed to clays migrates from clay edges to clay inter-layer spaces. The strength of partitioning of COIs from groundwater to solids ranges from loosely bound by ion exchange reactions to irreversibly bound in clay structures or chemical precipitates. By example, through the method of selective or partial extractions (Tessier et al., 1979) mineral phases and sediment fractions associated with higher concentrations of COIs through attenuation can be identified. By mineral or size separation and chemical extraction, the solids that contribute to attenuation can be classified and segregated for degree of effect. The degree of COI partitioning (Kd and µ) over a range of concentrations can be determined by testing co- located solids and groundwater, or the examination of COI concentration over time in groundwater at a fixed location for the purpose of solving the ADE. This and other information is used to calculate the amount of COI removal and time to achievement of remedial objectives using a MNA remedial approach. Role of Site Lithology Typically, geologic materials are sampled off site and away from potential contamination to establish baseline values for comparison to those analyzed from study sites. In lieu of detailed offsite sampling, published values for average crustal abundances can be utilized to evaluate whether indigenous materials contribute to COI concentrations in an area. For this report, crustal abundance values from Wedepohl (1978) are used for comparison to samples analyzed at the Dan River site. Table 5 presents average crustal abundances for comparison. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 18 of 25 Site Geologic Formation Influence on COI Occurrence Arkose - The Pine Hall Formation is the dominant lithology underlying the site and consists predominantly of arkosic sandstones and conglomerates. The clasts in the unit are dominated by metapelites derived from the Carolina Slate Belt. These units are interpreted to be fanglomerate deposits near the locus of basin sedimentation during the Triassic (Thayer et al., 1970). Accordingly, these immature units contain nearly sub-equal proportions of quartz, feldspar, and clays (predominantly illite/muscovite) (Table 6-1, DRSS CSA Report). Whole rock chemical analyses show abundances of antimony, arsenic, boron, chromium, cobalt, selenium, thallium, and vanadium within typical crustal abundances for sandstones and conglomerates of the region. Accordingly, weathering of the Pine Hall Formation contributes very little to any elevated values for COIs. Shale - The Cow Branch Formation is a subordinate lithology of limited exposure in the study area. It consists of shales, mudstones, pyritic-shale, and carbonaceous shales formed in lacustrine environments within a rift basin (Thayer et al., 1970). Samples with muscovite/illite concentrations over 50 percent probably represent this particular lithology. Similar to the Pine Hall Formation, the abundances of COIs in this unit are typically low with respect to average crustal abundance. Diabase - A diabase dike bisects the site and represents a fairly unique lithology with respect to the dominant types. Mafic rocks typically contain higher V and Co concentrations on average compared to sedimentary rocks and could cause elevated values in zones of significant weathering. Especially Co which tends to concentrate during the weathering process in residual soil profiles as illustrated at the site (Fig. 5-4, DRSS CSA Report). However, no sampling appears to have been attempted in proximity to the diabase unit. Biotite Gneiss – Outcroppings of biotite gneiss occur down gradient and across the Dan River, adjacent to the study site. Although not immediately connected to the hydrologic system at the site, the proximity of these rock units as a potential source of COIs should be considered. However, based on the crustal abundances of biotite gneiss it is not anticipated that any significant elevation in COIs could be derived from the gneisses. Soil Development Influence on COI Occurrence Soil formation typically results in the loss of common soluble cations and the accumulation of quartz and clay. Feldspars are hydrolyzed to clays. Concentrations of COIs liberated during the bedrock weathering and soil development on the lithologies noted above are negligible other than for a potential increase in vanadium and cobalt from diabase weathering. Soil chemistry results do not show marked deviation from normal crustal abundances at the site (Tables 6-2 and 6-3, DRSS CSA Report). Accordingly, the indigenous soils do not appear to contribute significantly to the COI abundances in the soils. Mechanisms for Natural Attenuation at DRSS Active precipitation of COI secondary minerals at the site appears unlikely, with exception of iron and manganese oxides and oxyhydroxides. The very low abundances of the other elements suggest saturation of these elements and precipitation as secondary oxides, arsenates, or carbonates is not attained. The attenuation of chemical contamination by reaction with existing natural materials may play a significant role at the site. The abundant clay content of the soils and host rock lithologies suggests much of the COI concentrations in the ash basin and ash storage may be attenuated by these materials. Harder (1970) and Perry (1972) showed in pioneering studies that boron is M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 19 of 25 adsorbed and incorporated into illite and chloritic clays respectively. The low content of boron in most rivers is attributed to the same processes. Thallium is also documented to be adsorbed to clays, especially potassium and rubidium types, as well as to iron and manganese oxides. Vanadium is also adsorbed and incorporated into clay structures and oxide coatings (Butler, 1953). Krauskopf (1956) suggests vanadium displays a preference for adsorption in decreasing order from Fe oxides > Mn oxides > montmorillonite > organic matter. In addition to the reported abundance of clays at the site, there is significant potential for more clay to be present as an alteration product on the surfaces of the abundant feldspars reported in the soils and rocks. Adsorption to iron oxides and hydroxides has long been demonstrated for As, B, Ba, Cd, Co, Cr, Co, Fe(II), Hg, Mn, Ni, Pb, Sb, Se, SO4-2, V and Zn (Dzomback and Morel, 1990). Soil chemistry results show abundant Fe2O3 and MnO values in soils from the site (Table 6-2, DRSS CSA Report) and a strong potential for adsorption. High Al2O3 (aluminum hydroxide) content is an indicator of clay minerals and also can indicate the presence common in soil-forming aluminum oxyhydroxides gibbsite, boehmite and diaspore. Adsorption to most-common gibbsite has been demonstrated for As, B, Cd, Co, Cr, Co, Fe(II), Hg, Mn, Ni, Pb, Se, SO4-2, and Zn (Karamalidis and Dzomback, 2010). The high amorphous content, 18 to 30 percent in the soil mineralogy from the site (Table 6-4, DRSS CSA Report), suggests a strong potential for COI adsorption in the site soils on amorphous Fe-Mn-Al oxide-hydroxides or on amorphous organic materials. Tier II Discussion & Conclusions Following successful completion of a Tier I demonstration that antimony, arsenic, boron, chromium, cobalt, selenium, and thallium are attenuating in groundwater at the site, a conceptual model for COI attenuation involving reversible and irreversible interaction with clay minerals, metal oxides, and organic matter is proposed. A Tier II demonstration based on that conceptual model was partially executed. The findings follow: 1. The sampling obtained geomedia representative of the material that the COI plume will traverse. 2. Clay minerals and iron oxides were found in all samples. Organic matter is probably not a significant sink for COI at the site. 3. Chemical extractions identified that COIs were concentrated in samples exposed to groundwater containing higher concentrations of COIs, validating the attenuation conceptual model. 4. Chemical extractions were used to determine a probable range of Kd values that suggest attenuation is taking place for antimony, arsenic, boron, chromium, cobalt, selenium, thallium, and vanadium. 5. Additional data collection is necessary to complete the Tier II assessment with respect to specific attenuation mechanisms for each COI, and quantification of the magnitude of that attenuation by specific geomedia to support numerical modeling. Data Gaps and Recommendations Tier II demonstrations address the mechanism and rate of attenuation. The mineralogical and physical characterization of solids with respect to type and adsorbed COI concentrations leads to predictions of COI attenuation expected in the future. Selective extraction (wet chemical analysis of solids), hydrostratigraphy, and broad water quality data collection provide part of the information needed to compare MNA to other remedial alternatives in the Tier II evaluation. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 20 of 25 The data collected to date has provided critical information on using MNA at DRSS and supports Tier II evaluations. To continue to Tier II and advance to Tier III, additional data collection is necessary. The data evaluation and analysis process for MNA is complex and iterative. The following table proposes some specific geochemical analysis approaches to completing Tier II evaluation of mechanism and support Tier III determinations of attenuation capacity of COIs. Many of these methods can be performed on archived materials. It was noted in the Tier I evaluation that additional solid-water pair data is needed from areas of higher concentration to improve the fit to these field adsorption isotherms (Field Kd). This will provide opportunity for additional data collection on samples that may be unavailable in archive. Field testing to determine dispersivity would also require redeployment to the site for testing activities. Analysis Group Action Method Purpose Wet Chemical Analysis Partial Extractions of Sediments Chemical extractions with differing degrees of action. Chemical analysis of extracts provides information on what solid materials the COI is associated with and the COI concentration on those materials. Total Analysis Complete digestion of sediment. Method 3052. HNO3 + HF digestion provides a total COI analysis of solid matrix to compare with partial extractions. More sensitive for trace metals than oxide analysis. Physical Analysis Field Sedimentology Field logging and classification by geologist. Record used for field selection of samples for preservation and analysis, selection of screen elevations for well installation, and correlation of stratigraphy between borings. Office Petrography Mineralogy by visual examination by geologist. Bulk samples and thin section. Optical and electron microscopy. Knowledge of the aquifer mineralogy and relative percentages of minerals is needed to evaluate observed groundwater chemistry and potential for COI attenuation by reaction with aquifer solids. XRD Reitveld Mineral identification by X-Ray Diffraction. Used to identify clay minerals and confirm/ support visual determinations of mineralogy. EDS Energy Dispersive Spectroscopy Provides information on the location and relative concentration of trace elements on mineral surfaces and polished sections. Hydrologic Parameters Tracer tests and break-through curve analysis. Site-specific determinations of dispersivity are needed Surface Chemistry Surface area of sediments. Determination of reactive area of the aquifer material. Needed to scale the results of chemical determination. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 21 of 25 REFERENCES AND CITATIONS Butler, J.R., 1953, The geochemistry and mineralogy of rock weathering. I. The Lizard area: Geochimica et Cosmochimica Acta, v. 4, p. 157. Dzomback and Morel, 1990. Dzomback, D.A., Morel, F.M.M., 1990. Surface Complexation Modeling: Hydrous Ferric Oxide. John Wylie and Sons, New York. EPRI, 2005. Chemical Constituents in Coal Combustion Product Leachate: Boron, EPRI, Palo Alto, CA. 2005. 1005258. EPRI, 2006. Groundwater Remediation of Inorganic Constituents at Coal Combustion Product Management Sites: Overview of Technologies, Focusing on Permeable Reactive Barriers. EPRI, Palo Alto, CA: 2006. 1012584. Goldberg et al., 2000. Goldberg, S., Lesch, S. M., and D. L. Suarez. Predicting Boron Adsorption by Soils Using Soil Chemical Parameters in the Constant Capacitance Model. Soil Sci. Soc. Am. J., 64(5): 1356-1363, 2000. Harder, H., 1970, Boron content of sediments as a tool in facies analysis: Sedimentary Geology, v. 4, p. 153. Herbelin and Westall, 1999. A. L. Herbelin and J. C. Westall. FITEQL - A Computer Program for Determination of Chemical Equilibrium Constants from Experimental Data. Report 99- 01, Department of Chemistry, Oregon State University, Corvallis, OR 97331. 1999. ITRC, 2010. A Decision Framework for Applying Monitored Natural Attenuation Processes to Metals and Radionuclides in Groundwater. APMR-1. 2010. Interstate Technology & Regulatory Council Karamalidis and Dzomback, 2010. Karamalidis, A. K., Dzomback, D.A., 2010. Surface Complexation Modeling: Gibbsite. John Wylie and Sons, New York. Krauskopf, K., 1955, Sedimentary deposits of rare metals: Economic Geology, v. 50, p. 411. Perry, E.A. Jr., 1972, Diagenesis and the validity of the boron paleosalinity technique: American Journal of Science, v. 272, p. 150. Tessier 1979. Tessier, A., Campbell, P. G. C., and M. Bisson. Sequential Extraction Procedure for the Speciation of Particulate Trace Metals. Analytical Chem., 51(7)844-850. Thayer et al., 1970. Thayer, P.A., Kirstein, D.S., and Ingram, R.L., 1970, Stratigraphy, sedimentology, and economic geology of Dan River Basin, North Carolina: Carolina Geological Society Guidebook, 29p. Toride et al., 1999. Toride, N., F.J. Leij, and M.Th. van Genuchten, The CXTFIT Code for Estimating Transport Parameters from Laboratory or Field Tracer Experiments: Version 2.1. US Department of Agriculture, Agricultural Research Service, US Salinity Laboratory, April, 1999. Research Report No. 137 M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 22 of 25 USEPA, 1999. Understanding Variation in Partition Coefficient, Kd, Values. Volume I: The Kd Model Of Measurement, And Application Of Chemical Reaction Codes. EPA 402-R-99- 004A. United States Environmental Protection Agency, Office of Air and Radiation, August 1999. USEPA, 2007. Monitored Natural Attenuation of Inorganic Contaminants in Groundwater, Vol. 1: Technical Basis for Assessment. 2007. US EPA, EPA/600/R-07/139. USGS, 2009. Harden, S L., M J. Chapman, and D A. Harned. Characterization of Groundwater Quality Based on Regional Geologic Setting in the Piedmont and Blue Ridge Physiographic Provinces, North Carolina. U.S. Geological Survey Scientific Investigations Report 2009–5149. USGS, 2013. Chapman, M.J., C. A. Cravotta III, Z. Szabo, and B.D. Lindsey. Naturally Occurring Contaminants in the Piedmont and Blue Ridge Crystalline-Rock Aquifers and Piedmont Early Mesozoic Basin Siliciclastic-Rock Aquifers, Eastern United States. 1994– 2008. U.S. Geological Survey Scientific Investigations Report 2013–5072. M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 23 of 25 Table 3. Solid-water pairs used for Tier I demonstration - DRSS Soil Aluminum Aluminum Antimony Antimony Arsenic Arsenic Barium Barium Boron Boron Beryllium Beryllium Cadmium Cadmium Chromium Chromium Cobalt Cobalt Copper Copper Iron Iron Lead Lead Mangane se Mangane se Mercury Mercury Molybden um Molybden um Nickel Nickel Selenium Selenium Strontium Strontium Thallium Thallium Vanadium Vanadium Zinc Zinc mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L mg/kg µg/L AS-12S(15-16.5)18600 13.1 0.24 8.2 0.48 98.1 33 1.5 1000 0.2 34.1 0.22 17.5 2 40.3 0.4 43200 82.6 21.5 479 420 0.02 4.9 2.8 39.4 9.6 69.6 600 32.6 0.29 86.9 AS-12S(20-21.5)22700 13.1 0.24 8.5 0.48 62.4 33 1.2 1000 0.2 36.1 0.22 26.2 2 70.1 0.4 44800 82.6 15.5 396 420 0.012 4.6 2.8 41.9 9.6 5.6 56.5 600 33.2 0.29 99.8 GWA-12S(13-15)32900 21 30.6 200 53 2 60.1 48.7 23.9 67.5 1 58700 21.5 698 102 0.009 5.6 41.9 2.14 72.5 140 67.2 119 6 GWA-6S(9-11)2610 2.4 31.9 200 0.16 620 8.9 0.9 3.5 2.5 4.4 5260 25300 3.8 97.9 3900 0.0072 13.7 3.2 1.4 3.6 860 0.14 12.1 11.9 2.7 GWA-6S(13.0-14.0)10700 2.4 110 200 0.61 620 24.7 0.9 13.6 2.5 16 20300 25300 7.9 237 3900 0.018 13.7 11 1.4 21 860 0.14 52.4 34.3 2.7 GWA-7S(16-17)10100 420 131 25 0.96 38 4.7 0.46 21.9 0.95 9.6 19.2 15 1 17600 16.2 659 1000 0.0074 12 51.1 0.62 21.2 780 28.1 37.8 560 GWA-7S(22-23)12900 420 3.2 195 25 2.3 38 4.7 0.46 17.9 0.95 16.3 19.2 13.6 1 25600 20.2 567 1000 23.6 51.1 6.1 0.62 32.8 780 22.8 74.2 560 GWA-10D(31.8-32.8)4620 9 52.1 55 1.4 172 0.38 8.2 6 2.11 13.5 7.79 23700 146 4.6 1.04 579 453 11.8 6.43 24.5 381 6.7 0.324 35.1 13 MW-318D(42.5-43.42 2420 21 1 14.9 35 0.24 1250 1 1 2.4 1 5.4 12.9 1.5 1.38 5130 588 8.2 1 210 607 0.011 1 5.1 12.4 1 11.1 589 0.2 3.9 0.3 17.3 78 OW-301D 10.4 10.8 162 157 186 3.4 23.6 4.5 11.9 2.3 39,400 3,190 246 159 1.2 61.2 3.6 3.6 OW-302D 5.2 83.6 16.6 44.8 3.1 0.67 21.5 2.2 40 14.4 34,800 188 338 337 1.7 2.9 30.6 OW-307D 8.3 180 13.8 27.1 15.4 7.7 3.6 14,400 359 522 55 2.8 5 17.6 OW-308D 0.86 76 543 577 39.4 11.4 407 17.3 0.48 37.3 6,840 26,000 66.3 1,310 1.4 3.1 3.6 0.41 47.2 OW-308D 543 106 39.4 407 0.65 17.4 15 37.3 25,800 26,000 182 1,310 0.075 3.1 0.61 0.35 26.8 OW-309D 2.6 53.1 386 440 489 45.3 466 20.1 6.6 4.9 3.5 5,430 2,470 52.9 553 1.7 16.4 2.1 1.5 5.5 72.9 20.9 OW-309D 1.1 27.6 386 269 489 6.6 466 8.1 6.6 1.1 3.5 5,380 2,470 75.2 553 0.86 16.4 2.9 5.5 26.4 20.9 OW-310D 13.4 713 197 433 921 1.2 65.5 5.1 1.1 8.7 28,600 7,080 354 1,880 2.3 30.1 1.7 9.6 70.6 14 OW-312D 2.8 102 77.5 502 0.82 15.4 5 10.8 26.2 31,500 20,800 665 3,040 0.046 4.2 0.65 27.8 9 OW-312D 90.6 77.5 502 22.3 5 2.3 26.2 13,800 20,800 156 3,040 4.2 0.87 0.41 34.3 9 OW-312D 68.8 77.5 502 13.5 5 3.6 26.2 7,110 20,800 114 3,040 0.054 4.2 0.68 0.37 20.8 9 OW-315D 228 72.1 114 1,290 4.6 15.4 22 16.3 52,000 10,700 326 542 0.046 16.5 1.1 52.4 M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 24 of 25 Table 4. Kd data used for Tier I evaluation - DRSS Dan River DRAFT Batch Tests AB-30BR AB-30BR AB-30BR AB-30BR AB-10SL AB-10SL AS-2D AS-2D GWA-10 GWA-11 GWA-5BR GWA-5BR GWA-4D GWA-4D GWA-11D GWA-11D GWA-12D GWA-12D GWA-1S GWA-1S GWA-3S GWA-3S Kd ml/g 32-34 FT 32-34 FT 43-44.1 FT 43-44.1 FT 48-50 FT 48-50 FT 47-50 FT 47-50 FT 102-104 FT 102-104 FT 8-12 FT 8-12 FT 38 FT 38 FT 23-25 FT 23-25 FT 20-21 FT 20-21 FT 33-35 FT 33-35 FT 25-27 FT 25-27 FT Arsenic 2563 2476 1975 1929 1868 1781 478 527 83 84 548 522 1007 1062 1750 1649 725 670 1744 1714 1339 1494 Boron 2 2 1 2 1 4 4 3 3 3 2 3 3 Cadmium 194 202 350 452 650 724 560 794 154 164 244 255 125 126 463 477 Chromium 20 34 Cobalt 365 430 225 2752 2815 2464 2378 748 717 558 1370 1334 Iron 536 7263 Manganese 18 17 13 14 182 187 79 78 4 4 0 0 6 6 64 66 15 9 58 57 40 40 Molybdenum 352 384 10 1486 1524 2257 2258 445 535 Antimony 936 1125 210 195 28 39 14 15 46 45 187 190 136 123 24 25 772 824 117 103 Selenium 1239 1324 180 176 115 125 58 60 135 121 1067 1165 2869 2703 55 50 3830 4082 1313 1553 Thallium 576 585 3142 3268 3790 3915 718 726 379 382 1100 1070 3980 3949 547 551 2139 2767 Vanadium 583 546 409 436 65 67 429 383 425 342 1345 Column Tests AB-30BR AB-30BR AB-30BR AB-30BR AB-10SL AS-2D AS-10D GWA-11 GWA-5BR GWA-4D GWA-11D GWA-12D GWA-1S GWA-3S Kd ml/g 32-34 FT 43-44.1 FT 43-44.1 FT 43-44.1 FT 48-50 FT 47-50 FT 10-11 FT 102-104 FT 8-12 FT 38 FT 23-25 FT 20-21 FT 33-35 FT 25-27 FT Median Min Max Max/Min Arsenic 370 420 400 450 350 210 290 30 30 700 475 40 370 150 360 30 700 23.3 Boron 12 25 20 15 12 10 12 8 8 8 12 8 15 9 12 8 25 3.1 Cadmium 360 530 500 460 390 290 135 370 175 290 650 340 400 315 365 135 650 4.8 Chromium Cobalt Iron Manganese Molybdenum 180 130 50 50 18 15 130 6 10 130 210 9 180 70 60 6 210 35.0 Antimony Selenium 285 230 110 120 100 60 160 15 18 210 400 20 285 130 125 15 400 26.7 Thallium 375 600 680 620 390 280 190 50 425 300 650 340 425 575 408 50 680 13.6 Vanadium 350 390 275 370 340 80 210 15 30 290 475 40 325 140 283 15 475 31.7 Kd ml/g Batch Median Column Median Batch Max/Min Column Max/Min Arsenic 1416 360 31.1 23.3 Boron 2.5 12 3.5 3.1 Cadmium 302 365 6.4 4.8 Chromium 27 1.7 Cobalt 1041 12.5 Iron 3899 13.5 Manganese 18 621.7 Molybdenum 535 60 237.7 35.0 Antimony 120 81.5 Selenium 624 125 82.5 26.7 Thallium 1085 408 10.5 13.6 Vanadium 425 283 20.6 31.7 M. Filardi DRSS MNA Tier I & II October 12, 2015 Page 25 of 25 Table 5. Average crustal abundances for lithologies at the Dan River Steam Station. (ppm) B V Cr Co As Se Sb Tl Arkose (Pine Hall Fm) 30 43 38 5 1.2 0.2 1 1 Shale (Cow Branch Fm) 130 110 62 19 12 0.3 2 2 Diabase 5 300 260 48 1.5 0.1 0.1 0.05 Biotite Gneiss 4 56 35 11 2 0.1 0.3 0.3 Summary of Statistically Derived Kd Values – Dan River Steam Station Variable Num Obs # Missing Minimum Maximum Mean SD SEM MAD/0.675 Skewness Kurtosis CV Arsenic 20 52 4 1440 404.4 383.6 85.78 209.8 1.644 2.969 0.949 Boron 22 47 0 19 4.136 4.063 0.866 2.224 2.657 8.561 0.982 Cadmium 31 41 25 6110 981.9 1192 214 607.9 2.966 11.2 1.214 Iron 4 35 24 25 24.25 0.5 0.25 0 2 4 0.020 6 Manganese 36 36 6 2247 170.7 414.9 69.15 50.41 4.148 18.92 2.431 Molybdenum 17 55 5 2057 208.2 529.4 128.4 8.895 3.176 10.29 2.543 Selenium 30 42 31 8721 1044 1996 364.5 177.9 2.941 8.837 1.912 Thallium 16 53 289 18354 2403 5166 1291 219.4 2.724 6.704 2.15 Vanadium 22 50 12 794 308.6 218.1 46.49 228.3 0.0783 -0.614 0.707 Cobalt 4 53 534 1196 899.8 322.4 161.2 349.1 -0.273 -4.211 0.358 Antimony 38 34 12 1007 139.8 255 41.36 37.81 2.637 5.715 1.824 Note: Prepared by Geochemical, LLC based on UNCC laboratory results. 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