Laboratory and initial field testing of the Min‐Trap™ for tracking reactive iron sulfide mineral formation during in situ remediation

Ulrich, Shannon; Tilton, Jennifer Martin; Justicia-Leon, Shandra D.; Liles, David; Prigge, Robert; Carter, Erika; Divine, Craig; Taggart, Dora; Clark, Katherine J.

doi:10.1002/rem.21681

Cited by 4 publications

(14 citation statements)

References 38 publications

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“…Although the increase in ferrous (dissolved) iron and decrease in sulfate concentrations, as well as the increased abundance of iron‐reducing bacteria and sulfate‐reducing bacteria, that occur following organic carbon amendment injections may be used as a proxy for the potential presence of reactive iron sulfide minerals, conclusive evidence of the formation of said minerals (i.e., direct mineralogical data) is generally lacking from performance monitoring programs. In a previous column entitled New Tools for Assessing Reactive Mineral‐Mediated Abiotic Contaminant Transformation (Horst et al 2019; Ulrich et al 2021), we describe the Min‐Traps, a specialized sampling device that can be deployed in conventional monitoring wells (with minimum well diameter of 2 in.) for the collection of reactive minerals for analysis.…”

Section: Performance Monitoring Considerationsmentioning

confidence: 99%

“…For example. Ulrich et al (2021) evaluated the Min-Trap technology in highly controlled sand tank tests where lactate was continuously injected for 175 days. AMIBA analyses of Min-Trap samples deployed in this tank confirmed the formation of substantial amounts of FeSx minerals (in excess of about 200 mg/kg in most locations).…”

Section: Performance Monitoring Considerationsmentioning

confidence: 99%

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Viewing the End from the Beginning: Designing for the Transition to Long‐Term Passive Phases of In Situ Chlorinated Solvent Treatment

Horst¹,

McCaughey²,

Justicia-Leon³

et al. 2022

Groundwater Monitoring Rem

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This column reviews the general features of PHT3D Version 2, a reactive multicomponent transport model that couples the geochemical modeling software PHREEQC-2 (Parkhurst and Appelo 1999) with three-dimensional groundwater flow and transport simulators MODFLOW-2000 and MT3DMS (Zheng and Wang 1999). The original version of PHT3D was developed by Henning Prommer and Version 2 by Henning Prommer and Vincent Post (Prommer and Post 2010). More detailed information about PHT3D is available at the website http://www.pht3d.org.The review was conducted separately by two reviewers. This column is presented in two parts.

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Section: Performance Monitoring Considerationsmentioning

confidence: 99%

Section: Performance Monitoring Considerationsmentioning

confidence: 99%

Viewing the End from the Beginning: Designing for the Transition to Long‐Term Passive Phases of In Situ Chlorinated Solvent Treatment

Horst¹,

McCaughey²,

Justicia-Leon³

et al. 2022

Groundwater Monitoring Rem

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“…A simulated aquifer tank was used for additional laboratory testing of the passive samplers. The tank test setup is described in detail in previous work (Ulrich et al, 2021), and was modified slightly from a single-pass flowthrough design to recirculation. The simulated aquifer tank consisted of a glass aquarium tank (46 cm wide, 122 cm long, and 41 cm tall), filled with 10 lateral centimeters of gravel (Imagitarium Nutmeg Aquarium Gravel) on each end and Ottawa sand in the body of the tank (Humboldt Manufacturing, Chicago, Illinois) mixed with 0.5 weight percent sand-sized limestone chips.…”

Section: Simulated Aquifer Tank Testmentioning

confidence: 99%

“…The tank was designed to accommodate five 2-inch diameter slotted PVC well screens. Ulrich et al (2021) operated the tank in a single-pass flow-through design; however, for this study, the effluent was collected and recirculated via a peristaltic pump. A three-pronged injection apparatus was built from 1/8-inch stainless steel Swagelok ® tubing, a four-way tee fitting, and two 90 elbow fittings.…”

Section: Simulated Aquifer Tank Testmentioning

confidence: 99%

Passive sampler designed for per‐ and polyfluoroalkyl substances using polymer‐modified organosilica adsorbent

et al. 2021

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A passive sampler designed to measure per-and polyfluoroalkyl substances (PFAS) was evaluated to determine chemical uptake rates under a variety of conditions. The sampler design is simple and robust, using organosilica modified with cross-linked amine polymer in an high density polyethylene housing retained with polypropylene mesh. The addition of amine groups as a weak ionexchange resin in combination with Cu 2+ was designed to promote binding of short-chain PFAS. A five-fold improvement in perfluorobutanoic acid adsorption was measured when Cu 2+ was added to the polyethylenimine polymer. The samplers showed an integrated response to all analytes tested except for shortchain PFAS. Sampling rates of PFAS analytes from simulated groundwater were on average 10 mL/day at flow rates of 0.038-1.9 cm/min. Relatively low variability in sampling rate was observed over the range of laboratory tested conditions (representing common conditions in environmental waters) including elevated ionic strength, sulfate concentration, and humic acid content.

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“…The recently developed mineral trap (known commercially as a Min-Trap ® ; Ulrich, Tilton, Ford, et al, 2021;…”

Section: Introductionmentioning

confidence: 99%

Field methods and example applications for the Min‐Trap® mineral sampler

Divine

Justicia-Leon

Tilton

et al. 2023

Remediation Journal

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Important reactive minerals are commonly created during in situ groundwater remediation activities; for example, iron sulfides formed during enhanced reduction approaches can abiotically degrade many chlorinated solvents. However, cost‐effective tools to evaluate these treatment processes in field applications are limited and the collection of samples to evaluate in situ mineral formation is costly due to drilling requirements. The new passive Min‐Trap sampler is a simple and cost‐effective tool that can directly measure the formation of reactive minerals in situ without the need for additional drilling or soil core collection. The methods presented here describe how Min‐Traps deployed in conventional monitoring wells can measure reactive minerals and how these minerals can be identified through commercially available analytical methods. Several examples are presented that show how Min‐Traps can be used to characterize the rate and spatial variability of reactive mineral precipitation and these data may support operation and optimization decisions.

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Laboratory and initial field testing of the Min‐Trap™ for tracking reactive iron sulfide mineral formation during in situ remediation

Cited by 4 publications

References 38 publications

Viewing the End from the Beginning: Designing for the Transition to Long‐Term Passive Phases of In Situ Chlorinated Solvent Treatment

Viewing the End from the Beginning: Designing for the Transition to Long‐Term Passive Phases of In Situ Chlorinated Solvent Treatment

Passive sampler designed for per‐ and polyfluoroalkyl substances using polymer‐modified organosilica adsorbent

Field methods and example applications for the Min‐Trap® mineral sampler

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