Enhancing oxygen evolution reaction via hydrogen plasma treatment: Unveiling the functionality of CN defects and the role of Fe in NiFe Prussian blue analogs

EcoEnergy Pub Date : 2024-04-27 DOI:10.1002/ece2.36
Qingdong Ruan, Dan Li, Chaoling Wu, Chao Huang, Paul K. Chu
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Abstract

The rational design of electronic and vacancy structures is crucial to regulating and enhancing electrocatalytic water splitting. However, creating novel vacancies and precisely controlling the number of vacancies in existing materials systems pose significant challenges. Herein, a novel approach to optimize the concentration of the CN vacancy (VCN) in the NiFe Prussian blue analog (PBA) nanocubes is designed by incorporating the H2 or O2 plasma treatment. The relationship between the VCN and catalysis is analyzed, and results show that a moderate concentration of VCN (6.5%) can enormously enhance oxygen evolution reaction (OER) activity of NiFe PBA. However, an excessive amount of VCN disrupts the crystal structure and hinders the transportation of charge carriers, consequently leading to inferior OER. Furthermore, the VCN significantly activates the activity of Fe sites, inducing preferential adsorption of OH on Fe sites, followed by adsorption on Ni sites, thereby optimizing the reaction pathway and significantly promoting OER performance. In addition, VCN also suppresses Fe leaching, giving the catalyst excellent durability. This study reveals the feasibility of creating unconventional defects in nanomaterials and precisely controlling the number of vacancies for diverse catalytic and energy applications.

Abstract Image

通过氢等离子体处理增强氧进化反应:揭示镍铁合金普鲁士蓝类似物中 CN 缺陷的功能性和铁的作用
合理设计电子和空位结构对于调节和增强电催化水分离至关重要。然而,在现有材料体系中创造新空位和精确控制空位数量是一项重大挑战。本文设计了一种新方法,通过结合 H2 或 O2 等离子处理来优化镍铁合金普鲁士蓝类似物(PBA)纳米立方体中的 CN 空位(VCN)浓度。结果表明,适度浓度的 VCN(6.5%)可极大地提高镍铁合金普鲁士蓝类似物(PBA)的氧进化反应(OER)活性。然而,过量的 VCN 会破坏晶体结构,阻碍电荷载流子的运输,从而导致 OER 效能降低。此外,VCN 还能显著激活铁位点的活性,诱导 OH- 优先吸附在铁位点上,然后再吸附在镍位点上,从而优化反应途径,显著提高 OER 性能。此外,VCN 还能抑制铁的浸出,使催化剂具有优异的耐久性。这项研究揭示了在纳米材料中制造非常规缺陷并精确控制空位数量以实现多种催化和能源应用的可行性。
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