Interaction of trace elements in acid mine drainage solution with humic acid

Interaction of trace elements in acid mine drainage solution with humic acid

The release of metal ions from a coal mining tailing area, Lamphun, Northern Thailand, is studied by leaching tests. Considerable amounts of Mn, Fe, Al, Ni and Co are dissolved in both simulated rain water (pH 4) and 10 mg L-1humic acid (HA) solution (Aldrich humic acid, pH 7). Due to the presence o...

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Main Authors: Siripat Suteerapataranon, Muriel Bouby, Horst Geckeis, Thomas Fanghänel, Kate Grudpan
Format: Journal
Published: 2018
Subjects:
Earth and Planetary Sciences
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http://cmuir.cmu.ac.th/jspui/handle/6653943832/61633
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-616332018-09-11T08:56:16Z Interaction of trace elements in acid mine drainage solution with humic acid Siripat Suteerapataranon Muriel Bouby Horst Geckeis Thomas Fanghänel Kate Grudpan Earth and Planetary Sciences The release of metal ions from a coal mining tailing area, Lamphun, Northern Thailand, is studied by leaching tests. Considerable amounts of Mn, Fe, Al, Ni and Co are dissolved in both simulated rain water (pH 4) and 10 mg L-1humic acid (HA) solution (Aldrich humic acid, pH 7). Due to the presence of oxidizing pyrite and sulfide minerals, the pH in both leachates decreases down to ∼3 combined with high sulfate concentrations typical to acid mine drainage (AMD) water composition. Interaction of the acidic leachates upon mixing with ground- and surface water containing natural organic matter is simulated by subsequent dilution (1:100; 1:200; 1:300; 1:500) with a 10 mg L-1HA solution (ionic strength: 10-3mol L-1). Combining asymmetric flow field-flow fractionation (AsFlFFF) with UV/Vis and ICP-MS detection allows for the investigation of metal ion interaction with HA colloid and colloid size evolution. Formation of colloid aggregates is observed by filtration and AsFlFFF depending on the degree of the dilution. While the average HA size is initially found to be {less-than or slanted equal to} 2 nm, metal-HA complexes are always found to be larger. Such observation is attributed to a metal induced HA agglomeration, which is found even at low coverage of HA functional groups with metal ions. Increasing the metal ion to HA ratio, the HA bound metal ions and the HA entities are growing in size from <3 to >450 nm. At high metal ion to HA ratios, precipitation of FeOOH phases and HA agglomeration due to colloid charge neutralization by complete saturation of HA complexing sites are responsible for the fact that most of Fe and Al precipitate and are found in a size fraction > 450 nm. In the more diluted solutions, HA is more relevant as a carrier for metal ion mobilization. © 2006 Elsevier Ltd. All rights reserved. 2018-09-11T08:56:16Z 2018-09-11T08:56:16Z 2006-06-01 Journal 00431354 2-s2.0-33646426388 10.1016/j.watres.2006.03.009 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=33646426388&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/61633
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Earth and Planetary Sciences
spellingShingle Earth and Planetary Sciences
Siripat Suteerapataranon
Muriel Bouby
Horst Geckeis
Thomas Fanghänel
Kate Grudpan
Interaction of trace elements in acid mine drainage solution with humic acid
description The release of metal ions from a coal mining tailing area, Lamphun, Northern Thailand, is studied by leaching tests. Considerable amounts of Mn, Fe, Al, Ni and Co are dissolved in both simulated rain water (pH 4) and 10 mg L-1humic acid (HA) solution (Aldrich humic acid, pH 7). Due to the presence of oxidizing pyrite and sulfide minerals, the pH in both leachates decreases down to ∼3 combined with high sulfate concentrations typical to acid mine drainage (AMD) water composition. Interaction of the acidic leachates upon mixing with ground- and surface water containing natural organic matter is simulated by subsequent dilution (1:100; 1:200; 1:300; 1:500) with a 10 mg L-1HA solution (ionic strength: 10-3mol L-1). Combining asymmetric flow field-flow fractionation (AsFlFFF) with UV/Vis and ICP-MS detection allows for the investigation of metal ion interaction with HA colloid and colloid size evolution. Formation of colloid aggregates is observed by filtration and AsFlFFF depending on the degree of the dilution. While the average HA size is initially found to be {less-than or slanted equal to} 2 nm, metal-HA complexes are always found to be larger. Such observation is attributed to a metal induced HA agglomeration, which is found even at low coverage of HA functional groups with metal ions. Increasing the metal ion to HA ratio, the HA bound metal ions and the HA entities are growing in size from <3 to >450 nm. At high metal ion to HA ratios, precipitation of FeOOH phases and HA agglomeration due to colloid charge neutralization by complete saturation of HA complexing sites are responsible for the fact that most of Fe and Al precipitate and are found in a size fraction > 450 nm. In the more diluted solutions, HA is more relevant as a carrier for metal ion mobilization. © 2006 Elsevier Ltd. All rights reserved.
format Journal
author Siripat Suteerapataranon
Muriel Bouby
Horst Geckeis
Thomas Fanghänel
Kate Grudpan
author_facet Siripat Suteerapataranon
Muriel Bouby
Horst Geckeis
Thomas Fanghänel
Kate Grudpan
author_sort Siripat Suteerapataranon
title Interaction of trace elements in acid mine drainage solution with humic acid
title_short Interaction of trace elements in acid mine drainage solution with humic acid
title_full Interaction of trace elements in acid mine drainage solution with humic acid
title_fullStr Interaction of trace elements in acid mine drainage solution with humic acid
title_full_unstemmed Interaction of trace elements in acid mine drainage solution with humic acid
title_sort interaction of trace elements in acid mine drainage solution with humic acid
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=33646426388&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/61633
_version_ 1681425657040470016

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