Thioarsenite Detection and Implications for Arsenic Transport in Groundwater.

Arsenic toxicity and mobility in groundwater depend on its aqueous speciation. Uncertainty about the methods used for measuring arsenic speciation in sulfate-reducing environments hampers transport and fate analyses and the development of in-situ remediation approaches for treating impacted aquifers. New anion-exchange chromatography methods linked to inductively coupled plasma mass spectrometry (ICP-MS) are presented that allow for sample/eluent pH matching. Sample/eluent pH matching is advantageous to prevent thioarsenic species transformation during chromatographic separation because: species protonation states remain unaffected, hydroxyl-for-bisulfide ligand substitution is avoided, and oxidation of reduced arsenic species is minimized. We characterized model and natural solutions containing mixtures of arsenic oxyanions with dissolved sulfide and solutions derived from the dissolution of thioarsenite and thioarsenate solids. In sulfidic solutions containing arsenite, two thioarsenic species with S/As ratios of 2:1 and 3:1 were important over the pH range from 5.5 to 8.5. The 3:1 thioarsenic species dominated when disordered As2S3 dissolved into sulfide-containing solution at pH 5.4. Together with the preferential formation of arsenite following sample dilution, these data provide evidence for the formation and detection of thioarsenite species. This study helps resolve inconsistencies between spectroscopic and chromatographic evidence regarding the nature of arsenic in sulfidic waters.

[1]  K. Scheckel,et al.  Response to Comment on "Thioarsenite Detection and Implications for Arsenic Transport in Groundwater". , 2020, Environmental science & technology.

[2]  F. Xiao,et al.  Adsorption and transformation of thioarsenite at hematite/water interface under anaerobic condition in the presence of sulfide. , 2019, Chemosphere.

[3]  J. Saunders,et al.  Field-scale bioremediation of arsenic-contaminated groundwater using sulfate-reducing bacteria and biogenic pyrite , 2018, Bioremediation Journal.

[4]  J. Saunders,et al.  Bioremediation of arsenic-contaminated groundwater by sequestration of arsenic in biogenic pyrite , 2018, Applied Geochemistry.

[5]  F. Xiao,et al.  The adsorption behavior of thioarsenite on magnetite and ferrous sulfide , 2018, Chemical Geology.

[6]  O. Abass,et al.  Effects of Fe-S-As coupled redox processes on arsenic mobilization in shallow aquifers of Datong Basin, northern China. , 2018, Environmental pollution.

[7]  D. Wiederin,et al.  Use of an inline dilution method to eliminate species interconversion for LC-ICP-MS based applications: focus on arsenic in urine , 2018 .

[8]  Xianjia Peng,et al.  Mechanisms of UV-Light Promoted Removal of As(V) by Sulfide from Strongly Acidic Wastewater. , 2017, Environmental science & technology.

[9]  M. Clench,et al.  The Investigation of Unexpected Arsenic Compounds Observed in Routine Biological Monitoring Urinary Speciation Analysis , 2017, Toxics.

[10]  Yan-xin Wang,et al.  Role of sulfur redox cycling on arsenic mobilization in aquifers of Datong Basin, northern China , 2017 .

[11]  G. Landrot,et al.  Arsenic Incorporation in Pyrite at Ambient Temperature at Both Tetrahedral S-I and Octahedral FeII Sites: Evidence from EXAFS-DFT Analysis. , 2017, Environmental science & technology.

[12]  J. Tong,et al.  Total arsenic and speciation analysis of saliva and urine samples from individuals living in a chronic arsenicosis area in China , 2016, Environmental Health and Preventive Medicine.

[13]  B. Planer-Friedrich,et al.  A new method for thioarsenate preservation in iron-rich waters by solid phase extraction. , 2016, Water research.

[14]  J. P. Maity,et al.  Natural Arsenic in Global Groundwaters: Distribution and Geochemical Triggers for Mobilization , 2016, Current Pollution Reports.

[15]  B. Planer-Friedrich,et al.  Anoxic, ethanolic, and cool – An improved method for thioarsenate preservation in iron-rich waters , 2015 .

[16]  R. Oremland,et al.  Anaerobic Chemolithotrophic Growth of the Haloalkaliphilic Bacterium Strain MLMS-1 by Disproportionation of Monothioarsenate. , 2015, Environmental science & technology.

[17]  L. M. Groskreutz,et al.  A new analytical approach to determining Mo and Re speciation in sulfidic waters , 2015 .

[18]  K. Williams,et al.  Thioarsenic species associated with increased arsenic release during biostimulated subsurface sulfate reduction. , 2014, Environmental science & technology.

[19]  A. Stefánsson,et al.  Determination of arsenic speciation in sulfidic waters by Ion Chromatography Hydride-Generation Atomic Fluorescence Spectrometry (IC-HG-AFS). , 2014, Talanta.

[20]  T. Townsend,et al.  Methodology for assessing thioarsenic formation potential in sulfidic landfill environments. , 2014, Chemosphere.

[21]  Guillermo Grindlay,et al.  A systematic study on the influence of carbon on the behavior of hard-to-ionize elements in inductively coupled plasma-mass spectrometry , 2013 .

[22]  S. Foster,et al.  Thio arsenic species measurements in marine organisms and geothermal waters , 2013 .

[23]  K. Williams,et al.  Arsenic geochemistry in a biostimulated aquifer: An aqueous speciation study , 2013, Environmental toxicology and chemistry.

[24]  B. Planer-Friedrich,et al.  Thioarsenate formation upon dissolution of orpiment and arsenopyrite. , 2012, Chemosphere.

[25]  T. Seward,et al.  A spectrophotometric study of the formation and deprotonation of thioarsenite species in aqueous solution at 22 °C , 2012 .

[26]  Robert L. Jones,et al.  A human urine standard reference material for accurate assessment of arsenic exposure , 2011 .

[27]  A. Ammann Arsenic Speciation Analysis by Ion Chromatography - A Critical Review of Principles and Applications , 2011 .

[28]  Andreas C Scheinost,et al.  Arsenic speciation in sulfidic waters: reconciling contradictory spectroscopic and chromatographic evidence. , 2010, Analytical chemistry.

[29]  B. Ravel,et al.  The New MRCAT (Sector 10) Bending Magnet Beamline at the Advanced Photon Source , 2010 .

[30]  B. Bostick,et al.  Changes in iron, sulfur, and arsenic speciation associated with bacterial sulfate reduction in ferrihydrite-rich systems. , 2009, Environmental science & technology.

[31]  B. Merkel,et al.  Discrimination of thioarsenites and thioarsenates by X-ray absorption spectroscopy. , 2009, Analytical chemistry.

[32]  B. Planer-Friedrich,et al.  A critical investigation of hydride generation-based arsenic speciation in sulfidic waters. , 2009, Environmental science & technology.

[33]  R. Wilkin,et al.  Performance of a zerovalent iron reactive barrier for the treatment of arsenic in groundwater: Part 2. Geochemical modeling and solid phase studies. , 2009, Journal of contaminant hydrology.

[34]  Robert L. Jones,et al.  Determination of seven arsenic compounds in urine by HPLC-ICP-DRC-MS: a CDC population biomonitoring method , 2009, Analytical and bioanalytical chemistry.

[35]  J. Tossell,et al.  Thermodynamic model for arsenic speciation in sulfidic waters: A novel use of ab initio computations , 2008 .

[36]  R. Wilkin,et al.  Examination of arsenic speciation in sulfidic solutions using X-ray absorption spectroscopy. , 2008, Environmental science & technology.

[37]  J. Hollibaugh,et al.  A new role for sulfur in arsenic cycling. , 2008, Environmental science & technology.

[38]  D. Nordstrom,et al.  Thioarsenates in geothermal waters of Yellowstone National Park: determination, preservation, and geochemical importance. , 2007, Environmental science & technology.

[39]  D. Wallschläger,et al.  Determination of (Oxy)thioarsenates in sulfidic waters. , 2007, Analytical chemistry.

[40]  B. Bostick,et al.  In situ analysis of thioarsenite complexes in neutral to alkaline arsenic sulphide solutions , 2005, Mineralogical Magazine.

[41]  F. Sacher,et al.  Thioarsenates in sulfidic waters. , 2005, Environmental science & technology.

[42]  M Newville,et al.  ATHENA, ARTEMIS, HEPHAESTUS: data analysis for X-ray absorption spectroscopy using IFEFFIT. , 2005, Journal of synchrotron radiation.

[43]  I. Koch,et al.  X-ray absorption near-edge structure analysis of arsenic species for application to biological environmental samples. , 2005, Environmental science & technology.

[44]  R. Root,et al.  The influence of sulfur and iron on dissolved arsenic concentrations in the shallow subsurface under changing redox conditions. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[45]  S. Hirata,et al.  Ion chromatography–inductively coupled plasma mass spectrometry determination of arsenic species in marine samples , 2004 .

[46]  A. Davis,et al.  Kinetics and mechanism of As2S3(am) dissolution under N2. , 2004, Environmental science & technology.

[47]  J. Ranville,et al.  Field and laboratory arsenic speciation methods and their application to natural-water analysis. , 2004, Water research.

[48]  R. Wilkin,et al.  Preservation of sulfidic waters containing dissolved As(III). , 2003, Journal of environmental monitoring : JEM.

[49]  R. Wilkin,et al.  Speciation of arsenic in sulfidic waters , 2003, Geochemical transactions.

[50]  R. Wilkin,et al.  Use of hydrochloric acid for determinining solid-phase arsenic partitioning in sulfidic sediments. , 2002, Environmental science & technology.

[51]  D. Janecky,et al.  A Raman spectroscopic study of arsenite and thioarsenite species in aqueous solution at 25°C , 2002, Geochemical transactions.

[52]  B. Bostick,et al.  Kinetics of Arsenate Reduction by Dissolved Sulfide , 2000 .

[53]  R. Wennrich,et al.  Determination of Anionic, Neutral, and Cationic Species of Arsenic by Ion Chromatography with ICPMS Detection in Environmental Samples. , 1998, Analytical chemistry.

[54]  M. Astruc,et al.  Chromatographic ion-exchange simultaneous separation of arsenic and selenium species with inductively coupled plasma-mass spectrometry on-line detection , 1997 .

[55]  G. Schwedt,et al.  Separation of thio- and oxothioarsenates by capillary zone electrophoresis and ion chromatography , 1996 .

[56]  R. Pattrick,et al.  Oligomerization in As (III) sulfide solutions: Theoretical constraints and spectroscopic evidence , 1995 .

[57]  S. Hansen,et al.  Speciation of eight arsenic compounds in human urine by high-performance liquid chromatography with inductively coupled plasma mass spectrometric detection using antimonate for internal chromatographic standardization , 1993 .

[58]  L. Eary The solubility of amorphous As2S3 from 25 to 90°C , 1992 .

[59]  J. Webster The solubility of As2S3 and speciation of As in dilute and sulphide-bearing fluids at 25 and 90° C , 1990 .

[60]  N. Spycher,et al.  As (III) and Sb(III) sulfide complexes: An evaluation of stoichiometry and stability from existing experimental data , 1989 .

[61]  D. Tallman,et al.  Arsenic species as an indicator of redox conditions in groundwater , 1979 .

[62]  P. Rieger,et al.  Oxygen-17 magnetic resonance study of oxygen exchange between arsenite ion and solvent water , 1978 .

[63]  D. Dyrssen Aquatic Chemistry—an introduction emphasizing chemical equilibria in natural waters , 1972 .

[64]  W. Nowacki,et al.  Refinement of the crystal structures of realgar, AsS and orpiment, As2S3 , 1972 .

[65]  G. Tunell,et al.  Solubility of orpiment (As2S3) in Na2S-H2O at 50–200°C and 100–1500 bars, with geological applications , 1966 .