Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint
The ability of biochar to immobilize metals relies on the amount of functional groups at its surface but the contribution of each functional groups (e.g. carboxylic, phenolic) to metal bonding is poorly known. Using a new approach based on previous works on rare earth element (REE) interactions with...
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doaj-cd05e659d7f6430ba5414691cd63b2f32020-11-25T00:09:21ZengElsevierHeliyon2405-84402018-02-014210.1016/j.heliyon.2018.e00543Characterization of metal binding sites onto biochar using rare earth elements as a fingerprintOlivier PourretDavid HoubenThe ability of biochar to immobilize metals relies on the amount of functional groups at its surface but the contribution of each functional groups (e.g. carboxylic, phenolic) to metal bonding is poorly known. Using a new approach based on previous works on rare earth element (REE) interactions with humic substances, we aim at elucidating the relative contribution of these binding sites to metal sorption under various conditions (i.e. pH and ionic strengths, IS). Using batch experiments, REE sorption onto biochar was analyzed from pH 3 to 9 and IS 10−1 mol/L to 10−3 mol/L. Rare earth element patterns show a Middle REE (MREE) downward concavity at acidic pH and low ionic strength. These patterns are in good agreement with existing datasets quantifying REE binding with humic substances. Indeed, the MREE downward concavity displayed by REE-biochar complexation pattern compares well with REE patterns with various organic compounds. This similarity in the REE complexation pattern shapes suggests that carboxylic groups are the main binding sites of REE in biochar. Overall, our results indicate that the strength of the metal bonding with biochar increases when pH and IS increase, suggesting that biochar is more efficient for long-term metal immobilization at near neutral pH and high ionic strength.http://www.sciencedirect.com/science/article/pii/S240584401732337XChemistryGeochemistryEnvironmental science |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Olivier Pourret David Houben |
spellingShingle |
Olivier Pourret David Houben Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint Heliyon Chemistry Geochemistry Environmental science |
author_facet |
Olivier Pourret David Houben |
author_sort |
Olivier Pourret |
title |
Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
title_short |
Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
title_full |
Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
title_fullStr |
Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
title_full_unstemmed |
Characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
title_sort |
characterization of metal binding sites onto biochar using rare earth elements as a fingerprint |
publisher |
Elsevier |
series |
Heliyon |
issn |
2405-8440 |
publishDate |
2018-02-01 |
description |
The ability of biochar to immobilize metals relies on the amount of functional groups at its surface but the contribution of each functional groups (e.g. carboxylic, phenolic) to metal bonding is poorly known. Using a new approach based on previous works on rare earth element (REE) interactions with humic substances, we aim at elucidating the relative contribution of these binding sites to metal sorption under various conditions (i.e. pH and ionic strengths, IS). Using batch experiments, REE sorption onto biochar was analyzed from pH 3 to 9 and IS 10−1 mol/L to 10−3 mol/L. Rare earth element patterns show a Middle REE (MREE) downward concavity at acidic pH and low ionic strength. These patterns are in good agreement with existing datasets quantifying REE binding with humic substances. Indeed, the MREE downward concavity displayed by REE-biochar complexation pattern compares well with REE patterns with various organic compounds. This similarity in the REE complexation pattern shapes suggests that carboxylic groups are the main binding sites of REE in biochar. Overall, our results indicate that the strength of the metal bonding with biochar increases when pH and IS increase, suggesting that biochar is more efficient for long-term metal immobilization at near neutral pH and high ionic strength. |
topic |
Chemistry Geochemistry Environmental science |
url |
http://www.sciencedirect.com/science/article/pii/S240584401732337X |
work_keys_str_mv |
AT olivierpourret characterizationofmetalbindingsitesontobiocharusingrareearthelementsasafingerprint AT davidhouben characterizationofmetalbindingsitesontobiocharusingrareearthelementsasafingerprint |
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1725412364015108096 |