Sulfur-facilitated in situ deep reconstruction of transition metal molybdates toward superior electrocatalytic oxidation of alkaline seawater

IF 11.5 Q1 CHEMISTRY, PHYSICAL

Chem Catalysis Pub Date : 2024-10-15 DOI:10.1016/j.checat.2024.101144

Zhan Zhao, Shiyu Qin, Xiang Li, Jianpeng Sun, Zizhen Li, Xiangchao Meng

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Abstract

Inducing the rapid and deep self-reconstruction of anodes has the potential to achieve the desired structure for effective oxygen evolution reactions (OERs) in seawater, but it is challenging. Herein, sulfur-assisted structural reconstruction of transition metal molybdates was fabricated. Benefiting from the electronic escape effect that occurs due to metal–O/–S bonding orbitals in the pre-catalyst, deep electrochemical reconstruction to highly active S-doped oxyhydroxides was achieved via rational S–metal hybridization and phase transition in the pre-catalyst. Meanwhile, combining the theoretical calculations and spectroscopic tests, it was found that introducing S atoms into oxyhydroxides activated lattice oxygen atoms, thereby boosting the intrinsic OER activity following the lattice oxygen mechanism pathway. As tested, the final S-doped oxyhydroxide catalysts exhibited excellent electrocatalytic activity with an ultralow overpotential of 166 mV at 10 mA cm⁻² in alkaline seawater oxidation. This work showcased a feasible strategy of sulfur-assisted structural reconstruction to fabricate highly efficient and chemically stable materials for seawater splitting.

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硫促进过渡金属钼酸盐原位深度重构，实现碱性海水的卓越电催化氧化作用

诱导阳极进行快速而深入的自我重构，有可能实现在海水中进行有效氧进化反应（OER）所需的结构，但这具有挑战性。在此，我们制作了硫辅助的过渡金属钼酸盐结构重构。利用前催化剂中金属-O/-S 键轨道产生的电子逸出效应，通过前催化剂中合理的 S 金属杂化和相变，实现了高活性 S 掺杂氧氢氧化物的深度电化学重构。同时，结合理论计算和光谱测试发现，在氧氢氧化物中引入 S 原子可激活晶格氧原子，从而按照晶格氧机制途径提高固有的 OER 活性。经测试，最终的掺 S 氧氢氧化物催化剂表现出优异的电催化活性，在碱性海水氧化过程中，10 mA cm-2 的过电位仅为 166 mV。这项工作展示了一种可行的硫辅助结构重构策略，可用于制造高效且化学性质稳定的海水分离材料。

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来源期刊

Chem Catalysis

CiteScore

10.50

自引率

6.40%

发文量

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.