消散
过电位
限制
电子设备和系统的热管理
纳米技术
能量转换
热的
析氧
载流子
化学
领域(数学)
工作(物理)
纳米电子学
催化作用
材料科学
化学物理
电场
电荷(物理)
电子
热能
机制(生物学)
化学能
碳纳米管
物理
相(物质)
作者
Hongyao Xue,Jiacheng Wang,Xiaodong Li,Yihao Li,Rongrong Cui,Yongzhe Li,Fengxia Deng,Mei Han,Huifang Li,Yan He,Shouhua Feng
摘要
ABSTRACT As a novel regulatory dimension, the alternating magnetic field (AMF) holds significant potential in enhancing the oxygen evolution reaction (OER). However, conventional AMF enhancements primarily rely on the suboptimal magnetothermal effect, which induces nonselective bulk heating and fails to provide targeted driving forces for catalysts, thereby severely limiting OER performance improvements. Here, a novel strategy has been demonstrated to precisely guide AMF energy from inefficient thermal dissipation to electron‐driven structural regulation by constructing energy dissipation channels for catalysts, which leads to the mechanism transformation from magnetothermal catalysis to electron‐driven catalysis. Typically, taking Fe 2 O 3 @CNTs as the research model, AMF induces localized electric fields that energize intrinsic charge carriers within Fe 2 O 3 . These energized electrons are then rapidly extracted by the carbon nanotubes (CNTs) network before they can undergo thermal relaxation. This efficient charge separation generates a high density of electron‐deficient, highly valent Fe sites on the Fe 2 O 3 surface, creating a potent localized chemical potential that drives deep structural reconstruction. Notably, the observed Duplex α/β ‐FeOOH phase is highly active, lowering the overpotential by 73 mV (∼22%) at 100 mA cm −2 . This work provides novel insight into magneto‐electrocatalysis and demonstrates that constructing energy dissipation channels is an efficient strategy for enhanced OER activity.
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