Symmetry-breaking CoN3S1 centers enable inert chloride ion adsorption for facilitating self-driven overall seawater splitting

IF 11.5 Q1 CHEMISTRY, PHYSICAL Chem Catalysis Pub Date : 2024-11-12 DOI:10.1016/j.checat.2024.101169
Canhui Zhang, Xu Liu, Cheng Zhen, Hanxu Yao, Liangliang Xu, Haibing Ye, Yue Wang, Xingkun Wang, M. Danny Gu, Minghua Huang, Heqing Jiang
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Abstract

A self-driven seawater splitting system could efficiently produce hydrogen from abundant seawater. However, high Cl concentrations in seawater lead to catalyst corrosion and deactivation, impairing performance in the oxygen reduction reaction (ORR), oxygen evolution reaction (OER), and hydrogen evolution reaction (HER). Here, we adopted single-atom Co-N-C-based catalysts, in which the electronic structure around the central Co site can be controlled and adjusted at an atomic level. Experimentally, the target N and S co-doped hollow carbon sphere (Co-N/S-HCS) catalyst, featuring asymmetric Co-N3S1 sites, shows excellent ORR/OER/HER performance. By employing density functional theory and molecular dynamics simulations of real-time simulations, we reveal that the S doped in the asymmetric Co-N3S1 model leads to a customized electronic structure around the central Co site, enabling weakened adsorption of the corrosive Cl and excellent ORR/OER/HER activities. Moreover, the seawater-based Zn-air batteries (S-ZABs) assembled by the Co-N/S-HCS deliver a cycling performance exceeding 650 h, and the overall seawater splitting system can run continuously for 1,100 h.

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打破对称的 CoN3S1 中心可实现惰性氯离子吸附,从而促进自驱动的整体海水分离
自驱动海水分离系统可从丰富的海水中高效制氢。然而,海水中高浓度的 Cl- 会导致催化剂腐蚀和失活,影响氧还原反应(ORR)、氧进化反应(OER)和氢进化反应(HER)的性能。在这里,我们采用了基于 Co-N-C 的单原子催化剂,在这种催化剂中,围绕中心 Co 位点的电子结构可以在原子水平上进行控制和调整。实验结果表明,目标 N 和 S 共掺杂空心碳球(Co-N/S-HCS)催化剂具有不对称 Co-N3S1 位点,显示出优异的 ORR/OER/HER 性能。通过采用密度泛函理论和分子动力学实时模拟,我们发现在非对称 Co-N3S1 模型中掺杂的 S 会导致围绕中心 Co 位点的定制电子结构,从而削弱对腐蚀性 Cl- 的吸附,实现优异的 ORR/OER/HER 活性。此外,Co-N/S-HCS 组装的海水型锌空气电池(S-ZABs)的循环性能超过 650 小时,整个海水分裂系统可连续运行 1100 小时。
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来源期刊
CiteScore
10.50
自引率
6.40%
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0
期刊介绍: Chem Catalysis is a monthly journal that publishes innovative research on fundamental and applied catalysis, providing a platform for researchers across chemistry, chemical engineering, and related fields. It serves as a premier resource for scientists and engineers in academia and industry, covering heterogeneous, homogeneous, and biocatalysis. Emphasizing transformative methods and technologies, the journal aims to advance understanding, introduce novel catalysts, and connect fundamental insights to real-world applications for societal benefit.
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