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

Divine, Craig; Justicia-Leon, Shandra D.; Tilton, Jennifer Martin; Carter, Erika; Zardouzian, Erik; Clark, Katherine J.; Taggart, Dora

doi:10.1002/rem.21752

Cited by 1 publication

(2 citation statements)

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“…These methods are generally consistent with similar sampling protocols described by Wilkin (2006) but do not require the use of a field glove box. Further detailed descriptions of field deployment, sampling, and preservation procedures are presented in Divine et al (2023).…”

Section: Min-trap Descriptionmentioning

confidence: 99%

“…The Min-Trap® sampler was specifically developed to address this challenge by providing a reliable and low-cost method to collect direct physical evidence of reactive mineral formation from monitoring wells without collecting soil/rock core samples. Results from laboratory prototype testing and an initial limited field pilot test were previously presented in Horst et al (2019) and Ulrich et al (2021aUlrich et al ( , 2021b, and specific details on Min-Trap sampling and preservation methods are presented in Divine et al (2023). This paper presents new data from a comprehensive field study designed to evaluate the performance and applicability of Min-Traps for collecting mineralogical data in the context of in-situ remediation of chlorinated solvents.…”

Section: Introductionmentioning

confidence: 99%

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Min‐Trap® Samplers to Passively Monitor In‐Situ Iron Sulfide Mineral Formation for Chlorinated Solvent Treatment

Divine,

Justicia‐León,

Tilton

et al. 2023

Groundwater Monitoring Rem

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The objective of this work was to field-demonstrate the Min-Trap® sampler technology, a new in-situ passive monitoring tool that offers distinct advantages for collecting mineralogical data. The Min-Trap consists of a solid porous medium (e.g., silica sand) contained within a waterpermeable mesh and support housing that is deployed inside a monitoring well. The porous medium serves as a solid substrate upon which target minerals passively form. Analysis of the sample medium using chemical, microscopic, spectroscopic, or other techniques can provide direct evidence of geochemical conditions and the formation of target minerals in-situ. The abiotic degradation of chlorinated volatile organic compounds via the reducing power stored in reactive minerals (e.g., iron sulfides) is a recognized important process, and Min-Traps are well suited to document the formation of these minerals during remediation. Min-Traps were tested in multiple wells at two field sites undergoing active remediation where reactive iron sulfide minerals were expected to be actively forming. Min-Trap samples were analyzed by a variety of analytical techniques, including total iron, acid volatile sulfide (AVS), chromium extractable sulfide (CrES; also known as chromium reducible sulfur; CRS), weak acid soluble (WAS) iron, strong acid soluble (SAS) iron, and scanning electron microscopy-energy dispersive X-ray spectroscopy (SEM-EDS). The results provided direct verification of iron sulfide minerals in all cases (n = 9) where they were expected or interpreted to be possibly present based on groundwater data. Min-Traps offer the potential for lifecycle cost savings because they do not require the collection of soil core samples, they can aid in better remedy implementation and performance, and they can potentially support earlier transition from active to passive remedy phases.

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Section: Min-trap Descriptionmentioning

confidence: 99%