Proton Self-Enhanced Hydroxyl-Enriched Cerium Oxide for Effective Arsenic Extraction from Strongly Acidic Wastewater

Proton Self-Enhanced Hydroxyl-Enriched Cerium Oxide for Effective Arsenic Extraction from Strongly Acidic Wastewater

Acid recycling and arsenic recovery from strongly acidic wastewater are goals of the metallurgical industry to reduce carbon emissions. In this study, arsenic was recovered using a hydroxyl-enriched CeO2 adsorbent, and the adsorption mechanism in a strongly acidic solution was investigated. The adso...

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Bibliographic Details
Published in:Environmental science & technology Vol. 56; no. 14; pp. 10412 - 10422
Main Authors: Hu, Wenbin, Yang, Liming, Shao, Penghui, Shi, Hui, Chang, Ziwen, Fang, Difan, Wei, Yun, Feng, Yufa, Huang, Yong, Yu, Kai, Luo, Xubiao
Format: Journal Article
Language:English
Published: Easton American Chemical Society 19-07-2022
Subjects:
Acidic oxides
Adsorption
Arsenic
Cerium
Cerium oxides
Emissions
Enrichment
Extractive metallurgy
Hydrogen ions
Hydroxyl groups
Metal industry
Metallurgical analysis
Oxidation
pH effects
Protons
Treatment and Resource Recovery
Wastewater
hydroxyl
adsorption
CeO2
strongly acidic wastewater
arsenic
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Summary:Acid recycling and arsenic recovery from strongly acidic wastewater are goals of the metallurgical industry to reduce carbon emissions. In this study, arsenic was recovered using a hydroxyl-enriched CeO2 adsorbent, and the adsorption mechanism in a strongly acidic solution was investigated. The adsorption capacities of 88.59 mg/g for As­(III) and 126.211 mg/g for As­(V) at pH 1.0 are the highest reported values to date. It is revealed that the hydroxyl groups on the CeO2 surface can buffer hydrogen ions, and the isoelectric point of the material can be reduced to pH 1.52. The binding energy of arsenic is −1.25 eV for the hydroxyl-enriched CeO2 and −2.24 eV for CeO2 without hydroxyl groups. Additionally, the protonated hydroxyl groups reduce the oxidation energy of As­(III) and promote the adsorption of arsenic by forming new active sites in the strongly acidic solution. Nearly 98.11% of arsenic (initial concentration is 886.8 mg/L) is removed within 24 h without pH adjustment, indicating the feasibility of hydroxyl-enriched CeO2 for recovering arsenic and acid. This work investigated the adsorption and proton-enhanced oxidation mechanism of arsenic by hydroxyl-enriched CeO2 in strongly acidic wastewater.
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ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.2c02675