Metal Speciation in Anoxic Sediments:  When Sulfides Can Be Construed as Oxides

Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using...

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Published inEnvironmental science & technology Vol. 39; no. 1; pp. 311 - 316
Main Authors Peltier, Edward, Dahl, Amy L, Gaillard, Jean-François
Format Journal Article
LanguageEnglish
Published Washington, DC American Chemical Society 01.01.2005
Subjects
Applied sciences
Arsenic
Biological and physicochemical properties of pollutants. Interaction in the soil
Chemistry Techniques, Analytical - methods
Contaminated sediments
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Environmental monitoring
Exact sciences and technology
Geologic Sediments - chemistry
Lead - analysis
Lead - chemistry
Metals
Oxides
Pollution
Pollution, environment geology
Reproducibility of Results
Sediments
Soil and sediments pollution
Spectrum Analysis
Sulfides - analysis
Sulfides - chemistry
Volatilization
Zinc - analysis
Zinc - chemistry
Volatile compound
Pollutant behavior
Sequential extraction
Artefact
Sediments
Zinc
Heavy metal
Sulfides
Pollution
X ray absorption spectrometry
Analysis method
Surface water
Lead
Measurement accuracy
Wetland
Measurement error
Speciation
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Abstract Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using X-ray absorption spectroscopy (XAS) and acid-volatile sulfide (AVS) analysis, we evaluated the effectiveness of one of the most widely used sequential extraction protocols, the Tessier method, at determining Zn and Pb speciation in anoxic wetland sediments. Sequential extraction results significantly underestimated the amount of Zn associated with sulfide phases as compared to the other two approaches. XAS analysis of ZnS amended sediments indicates that the most likely source of this conflict is an early dissolution of amorphous metal sulfide phases during the sequential extraction step corresponding to the extraction of iron and manganese oxides. The reagent mixture used in this step, hydroxylamine hydrochloride-HCl, is widely used in other sequential extraction protocols, including the BCR method, limiting their application to anoxic sediments. For this reason, current sequential extraction techniques should only be used on anoxic sediments with caution, and/or in conjunction with complementary approaches to assess metal speciation.
AbstractList Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using X-ray absorption spectroscopy (XAS) and acid-volatile sulfide (AVS) analysis, we evaluated the effectiveness of one of the most widely used sequential extraction protocols, the Tessier method, at determining Zn and Pb speciation in anoxic wetland sediments. Sequential extraction results significantly underestimated the amount of Zn associated with sulfide phases as compared to the other two approaches. XAS analysis of ZnS amended sediments indicates that the most likely source of this conflict is an early dissolution of amorphous metal sulfide phases during the sequential extraction step corresponding to the extraction of iron and manganese oxides. The reagent mixture used in this step, hydroxylamine hydrochloride-HCI, is widely used in other sequential extraction protocols, including the BCR method, limiting their application to anoxic sediments. For this reason, current sequential extraction techniques should only be used on anoxic sediments with caution, and/or in conjunction with complementary approaches to assess metal speciation. [PERIODICAL ABSTRACT]
Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using X-ray absorption spectroscopy (XAS) and acid-volatile sulfide (AVS) analysis, we evaluated the effectiveness of one of the most widely used sequential extraction protocols, the Tessier method, at determining Zn and Pb speciation in anoxic wetland sediments. Sequential extraction results significantly underestimated the amount of Zn associated with sulfide phases as compared to the other two approaches. XAS analysis of ZnS amended sediments indicates that the most likely source of this conflict is an early dissolution of amorphous metal sulfide phases during the sequential extraction step corresponding to the extraction of iron and manganese oxides. The reagent mixture used in this step, hydroxylamine hydrochloride-HCl, is widely used in other sequential extraction protocols, including the BCR method, limiting their application to anoxic sediments. For this reason, current sequential extraction techniques should only be used on anoxic sediments with caution, and/or in conjunction with complementary approaches to assess metal speciation.Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using X-ray absorption spectroscopy (XAS) and acid-volatile sulfide (AVS) analysis, we evaluated the effectiveness of one of the most widely used sequential extraction protocols, the Tessier method, at determining Zn and Pb speciation in anoxic wetland sediments. Sequential extraction results significantly underestimated the amount of Zn associated with sulfide phases as compared to the other two approaches. XAS analysis of ZnS amended sediments indicates that the most likely source of this conflict is an early dissolution of amorphous metal sulfide phases during the sequential extraction step corresponding to the extraction of iron and manganese oxides. The reagent mixture used in this step, hydroxylamine hydrochloride-HCl, is widely used in other sequential extraction protocols, including the BCR method, limiting their application to anoxic sediments. For this reason, current sequential extraction techniques should only be used on anoxic sediments with caution, and/or in conjunction with complementary approaches to assess metal speciation.
Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally defined and subject to artifacts, particularly when dealing with anoxic sediments, in which metal sulfide precipitates are likely to occur. Using X-ray absorption spectroscopy (XAS) and acid-volatile sulfide (AVS) analysis, we evaluated the effectiveness of one of the most widely used sequential extraction protocols, the Tessier method, at determining Zn and Pb speciation in anoxic wetland sediments. Sequential extraction results significantly underestimated the amount of Zn associated with sulfide phases as compared to the other two approaches. XAS analysis of ZnS amended sediments indicates that the most likely source of this conflict is an early dissolution of amorphous metal sulfide phases during the sequential extraction step corresponding to the extraction of iron and manganese oxides. The reagent mixture used in this step, hydroxylamine hydrochloride-HCl, is widely used in other sequential extraction protocols, including the BCR method, limiting their application to anoxic sediments. For this reason, current sequential extraction techniques should only be used on anoxic sediments with caution, and/or in conjunction with complementary approaches to assess metal speciation.
Author Peltier, Edward
Gaillard, Jean-François
Dahl, Amy L
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Keywords Volatile compound
Pollutant behavior
Sequential extraction
Artefact
Sediments
Zinc
Heavy metal
Sulfides
Pollution
X ray absorption spectrometry
Analysis method
Surface water
Lead
Measurement accuracy
Wetland
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Speciation
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Snippet Metal speciation in aquatic sediments is often characterized using wet chemical sequential extraction techniques. However, these methods are operationally...
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SubjectTerms Applied sciences
Arsenic
Biological and physicochemical properties of pollutants. Interaction in the soil
Chemistry Techniques, Analytical - methods
Contaminated sediments
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Environmental monitoring
Exact sciences and technology
Geologic Sediments - chemistry
Lead - analysis
Lead - chemistry
Metals
Oxides
Pollution
Pollution, environment geology
Reproducibility of Results
Sediments
Soil and sediments pollution
Spectrum Analysis
Sulfides - analysis
Sulfides - chemistry
Volatilization
Zinc - analysis
Zinc - chemistry
Title Metal Speciation in Anoxic Sediments:  When Sulfides Can Be Construed as Oxides
URI http://dx.doi.org/10.1021/es049212c
https://api.istex.fr/ark:/67375/TPS-27NX6MKH-G/fulltext.pdf
https://www.ncbi.nlm.nih.gov/pubmed/15667111
https://www.proquest.com/docview/230156711
https://www.proquest.com/docview/16192699
https://www.proquest.com/docview/67375067
Volume 39
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