{"title":"多重缺陷诱发的低旋 Fe3+,具有最佳中间吸附性,在水氧化过程中具有无与伦比的性能。","authors":"Yihao Wang, Shanqing Li, Xu Hou, Tingting Cui, Zechao Zhuang, Yunhe Zhao, Haozhi Wang, Wei Wei, Ming Xu, Qiang Fu, Chunxia Chen, Dingsheng Wang","doi":"10.1002/adma.202412598","DOIUrl":null,"url":null,"abstract":"<p><p>Electrocatalytic water splitting is long constrained by the sluggish kinetics of anodic oxygen evolution reaction (OER), and rational spin-state manipulation holds great promise to break through this bottleneck. Low-spin Fe<sup>3+</sup> (LS, t<sub>2g</sub> <sup>5</sup>e<sub>g</sub> <sup>0</sup>) species are identified as highly active sites for OER in theory, whereas it is still a formidable challenge to construct experimentally. Herein, a new strategy is demonstrated for the effective construction of LS Fe<sup>3+</sup> in NiFe-layered double hydroxide (NiFe-LDH) by introducing multiple defects, which induce coordination unsaturation over Fe sites and thus enlarge their d orbital splitting energy. The as-obtained catalyst exhibits extraordinary OER performance with an ultra-low overpotential of 244 mV at the industrially required current density of 500 mA cm<sup>-2</sup>, which is 110 mV lower than that of the conventional NiFe-LDH with high-spin Fe<sup>3+</sup> (HS, t<sub>2g</sub> <sup>3</sup>e<sub>g</sub> <sup>2</sup>) and superior to most previously reported NiFe-based catalysts. Comprehensive experimental and theoretical studies reveal that LS Fe<sup>3+</sup> configuration effectively reduces the adsorption strength of the O* intermediate compared with that of the HS case, thereby altering the rate-determining step from (O* → OOH*) to (OH* → O*) of OER and lowering its reaction energy barrier. This work paves a new avenue for developing efficient spin-dependent electrocatalysts for OER and beyond.</p>","PeriodicalId":114,"journal":{"name":"Advanced Materials","volume":" ","pages":"e2412598"},"PeriodicalIF":27.4000,"publicationDate":"2024-11-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Low-Spin Fe<sup>3+</sup> Evoked by Multiple Defects with Optimal Intermediate Adsorption Attaining Unparalleled Performance in Water Oxidation.\",\"authors\":\"Yihao Wang, Shanqing Li, Xu Hou, Tingting Cui, Zechao Zhuang, Yunhe Zhao, Haozhi Wang, Wei Wei, Ming Xu, Qiang Fu, Chunxia Chen, Dingsheng Wang\",\"doi\":\"10.1002/adma.202412598\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Electrocatalytic water splitting is long constrained by the sluggish kinetics of anodic oxygen evolution reaction (OER), and rational spin-state manipulation holds great promise to break through this bottleneck. Low-spin Fe<sup>3+</sup> (LS, t<sub>2g</sub> <sup>5</sup>e<sub>g</sub> <sup>0</sup>) species are identified as highly active sites for OER in theory, whereas it is still a formidable challenge to construct experimentally. Herein, a new strategy is demonstrated for the effective construction of LS Fe<sup>3+</sup> in NiFe-layered double hydroxide (NiFe-LDH) by introducing multiple defects, which induce coordination unsaturation over Fe sites and thus enlarge their d orbital splitting energy. The as-obtained catalyst exhibits extraordinary OER performance with an ultra-low overpotential of 244 mV at the industrially required current density of 500 mA cm<sup>-2</sup>, which is 110 mV lower than that of the conventional NiFe-LDH with high-spin Fe<sup>3+</sup> (HS, t<sub>2g</sub> <sup>3</sup>e<sub>g</sub> <sup>2</sup>) and superior to most previously reported NiFe-based catalysts. Comprehensive experimental and theoretical studies reveal that LS Fe<sup>3+</sup> configuration effectively reduces the adsorption strength of the O* intermediate compared with that of the HS case, thereby altering the rate-determining step from (O* → OOH*) to (OH* → O*) of OER and lowering its reaction energy barrier. 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引用次数: 0
摘要
长期以来,电催化水分离受制于阳极氧进化反应(OER)的缓慢动力学,而合理的自旋态操作则有望突破这一瓶颈。低自旋 Fe3+(LS,t2g 5eg 0)物种在理论上被认为是阳极氧进化反应的高活性位点,但要在实验中构建这一位点仍是一项艰巨的挑战。本文展示了一种在镍铁层双氢氧化物(NiFe-LDH)中有效构建 LS Fe3+ 的新策略,即通过引入多重缺陷来诱导 Fe 位点配位不饱和,从而提高其 d 轨道分裂能。获得的催化剂具有非凡的 OER 性能,在工业要求的 500 mA cm-2 电流密度下,过电位超低,仅为 244 mV,比传统的高自旋 Fe3+(HS,t2g 3eg 2)NiFe-LDH 低 110 mV,优于之前报道的大多数 NiFe 基催化剂。综合实验和理论研究发现,与 HS 情况相比,LS Fe3+ 配置有效降低了 O* 中间体的吸附强度,从而改变了 OER 的速率决定步骤,从(O* → OOH*)变为(OH* → O*),并降低了其反应能垒。这项工作为开发用于 OER 及其他反应的高效自旋依赖性电催化剂开辟了一条新途径。
Low-Spin Fe3+ Evoked by Multiple Defects with Optimal Intermediate Adsorption Attaining Unparalleled Performance in Water Oxidation.
Electrocatalytic water splitting is long constrained by the sluggish kinetics of anodic oxygen evolution reaction (OER), and rational spin-state manipulation holds great promise to break through this bottleneck. Low-spin Fe3+ (LS, t2g5eg0) species are identified as highly active sites for OER in theory, whereas it is still a formidable challenge to construct experimentally. Herein, a new strategy is demonstrated for the effective construction of LS Fe3+ in NiFe-layered double hydroxide (NiFe-LDH) by introducing multiple defects, which induce coordination unsaturation over Fe sites and thus enlarge their d orbital splitting energy. The as-obtained catalyst exhibits extraordinary OER performance with an ultra-low overpotential of 244 mV at the industrially required current density of 500 mA cm-2, which is 110 mV lower than that of the conventional NiFe-LDH with high-spin Fe3+ (HS, t2g3eg2) and superior to most previously reported NiFe-based catalysts. Comprehensive experimental and theoretical studies reveal that LS Fe3+ configuration effectively reduces the adsorption strength of the O* intermediate compared with that of the HS case, thereby altering the rate-determining step from (O* → OOH*) to (OH* → O*) of OER and lowering its reaction energy barrier. This work paves a new avenue for developing efficient spin-dependent electrocatalysts for OER and beyond.
期刊介绍:
Advanced Materials, one of the world's most prestigious journals and the foundation of the Advanced portfolio, is the home of choice for best-in-class materials science for more than 30 years. Following this fast-growing and interdisciplinary field, we are considering and publishing the most important discoveries on any and all materials from materials scientists, chemists, physicists, engineers as well as health and life scientists and bringing you the latest results and trends in modern materials-related research every week.