Article, 2024

Electrodeposited Palladium Nanoparticles Enhancing Atomic Hydrogen-Mediated Electrochemical Recovery of Antimony

ACS ES&T Engineering, ISSN 2690-0645, Volume 4, 7, Pages 1668-1678, 10.1021/acsestengg.4c00078

Contributors

Wei, Feng [1] [2] Qiu, Xianhua [2] Wang, Bowen 0000-0001-7002-7901 [3] Lu, Sen 0000-0001-5486-5673 [4] Zhang, Liying [4] Yi, Genping (Corresponding author) [2] [4] Feng, Yufa [2] Nie, Jiawei [2] Shao, Penghui [2] Liu, Wen-Zong 0000-0002-1331-6480 (Corresponding author) [4] Yang, Liming 0000-0002-0199-2297 (Corresponding author) [1] [2] Wang, Ai-Jie [4] Luo, Xu-Biao [2] [5]

Affiliations

  1. [1] Jiangxi Hongcheng Environment Co., Ltd., Nanchang, 330038, China
    2. [NORA names: China; Asia, East];
  2. [2] Nanchang Hangkong University
    3. [NORA names: China; Asia, East];
  3. [3] Aarhus University
    4. [NORA names: AU Aarhus University; University; Denmark; Europe, EU; Nordic; OECD];
  4. [4] Harbin Institute of Technology
    5. [NORA names: China; Asia, East];
  5. [5] Jinggangshan University
    6. [NORA names: China; Asia, East]

Abstract

Electro-generated atomic hydrogen (H*) emerges as a potent species for water contaminant remediation, yet its short life span and confinement to the electrode–solution interface have restricted its broader application. Herein, we investigated the efficacy of palladium nanoparticles loaded onto a carbon cloth (hereafter the Pd/CC) electrode in stabilizing surface atomic H* and enhancing its electroreduction performance against toxic antimonite Sb­(III). In comparison to the CC electrode, the Pd/CC electrode exhibited a 0.4 V increase in the onset potential of H+ electroreduction and a 5.5-fold improvement in electrochemically active surface area. Additionally, the Sb­(III) removal rate constant and metallic antimony (Sb0) formation on the Pd/CC electrode surface were increased by 2.2- and 5.1-fold, respectively. Quenching experiments showed a 20% reduction ratio of atomic H* to Sb­(III) at −1.0 V vs Ag/AgCl. Moreover, in situ trapping combined with semiquantification via electron spin resonance indicated that ca. 89% of atomic H* participated in Sb­(III) reduction. The exposed crystal surface of Pd nanoparticles increased the electron transport capacity and atomic H* coverage on the electrode surface, which provided a large number of reduction sites for the direct and indirect reductions of Sb­(III). Furthermore, accumulated reduction products were easily recovered in dilute H2SO4, rendering the electrode reusable. This work offers a practical and innovative solution for remediating heavy-metal-polluted wastewater and simultaneously recovering metal resources.

Keywords

CC electrode, H*, H* coverage, H2SO4, Pd nanoparticles, active surface area, antimony, applications, area, atomic H, atomic H*, atomic hydrogen, capacity, carbon, carbon cloth, clothing, comparison, contaminant remediation, coverage, crystal surface, dilute H2SO4, efficacy, electrochemically, electrochemically active surface area, electrode, electrode reusability, electrode surface, electrode-solution interface, electrodeposition, electron, electron spin resonance, electron transport capacity, electroreduction, experiments, exposed crystal surfaces, formation, hydrogen, improvement, in situ, increase, indirect reduction, innovative solutions, interface, life span, metal, metal resources, metallic antimony, nanoparticles, palladium nanoparticles, performance, potential, production, quenching, quenching experiments, recovery of antimony, reduction, reduction products, reduction ratio, reduction site, remediation, resonance, resources, reusability, semiquantification, short life span, sites, solution, span, species, spin resonance, surface, surface area, transport capacity, wastewater, water, water contamination remediation

Funders

  • National Natural Science Foundation of China
  • Danish National Research Foundation
  • Ministry of Science and Technology of the People's Republic of China

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