2024
DOI: 10.1002/adfm.202314621
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Regulating the Electronic Synergy of Asymmetric Atomic Fe Sites with Adjacent Defects for Boosting Activity and Durability toward Oxygen Reduction

Siqi Ji,
Yuhao Wang,
Hongxue Liu
et al.

Abstract: The oxygen reduction reaction (ORR) plays a fundamental role in sustainable energy technologies. However, the creation of non‐precious metal electrocatalysts with high ORR activity and durability under all pH conditions is of great significance but remains challenging. Herein, the aim is to overcome this challenge by creating a Fe single atom catalyst on a 2D defect‐containing nitrogen‐doped carbon support (Fe1/DNC) via a microenvironment engineering strategy. Microkinetic modeling reveals that FeN4(OH) moieti… Show more

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Cited by 12 publications
(1 citation statement)
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“…Transition metals anchored on a hierarchical porous carbon matrix have been regarded as highly efficient electrocatalysts due to the merits of their easily tunable electron configuration and highly exposed active sites. Typically, the d -block metal centers have been widely investigated for updating reduction activity via crystalline regulating, defect engineering, and metal elements tuning, due to their high surface-to-volume ratios and the presence of a multimetal atom structure. , In addition, the structure of the metal active centers can be modulated through heteroatom doping to enhance the catalytic activity and structural stability. Furthermore, the morphology and nanoscale structure of the catalyst can be adjusted to anchor and expose metal sites at the gas/liquid/solid triphasic interface, which facilitates the diffusion of gas molecules and the transport of O 2 to the active sites. However, the intricate local coordination environment and the difficulty in precise structure design present a challenge in establishing effective bifunctional catalysts.…”
Section: Introductionmentioning
confidence: 99%
“…Transition metals anchored on a hierarchical porous carbon matrix have been regarded as highly efficient electrocatalysts due to the merits of their easily tunable electron configuration and highly exposed active sites. Typically, the d -block metal centers have been widely investigated for updating reduction activity via crystalline regulating, defect engineering, and metal elements tuning, due to their high surface-to-volume ratios and the presence of a multimetal atom structure. , In addition, the structure of the metal active centers can be modulated through heteroatom doping to enhance the catalytic activity and structural stability. Furthermore, the morphology and nanoscale structure of the catalyst can be adjusted to anchor and expose metal sites at the gas/liquid/solid triphasic interface, which facilitates the diffusion of gas molecules and the transport of O 2 to the active sites. However, the intricate local coordination environment and the difficulty in precise structure design present a challenge in establishing effective bifunctional catalysts.…”
Section: Introductionmentioning
confidence: 99%