Low-dimensional design of precious metal-based catalysts in fuel cells

Peixi Qiu; Chengyong Shu; Zhoufan Gan; Jingwen Cao; Zhixu Chen; Hao Wu; Yuping Wu; Wei Tang

doi:10.1016/j.jpowsour.2025.236772

Low-dimensional design of precious metal-based catalysts in fuel cells

Peixi Qiu, Chengyong Shu, Zhoufan Gan, Jingwen Cao, Zhixu Chen, Hao Wu, Yuping Wu, Wei Tang

Research output: Contribution to journal › Review article › peer-review

Abstract

The development of low-dimensional noble metal catalysts has emerged as a critical pathway to address the cost-durability challenges in fuel cells. This review synthesizes recent advances in designing ultrathin nanowires, defect-engineered metalene, and strain-tuned nanosheets that demonstrate exceptional oxygen reduction SSreaction activity and cycling stability. We systematically decode three atomic-level enhancement mechanisms: (1) ligand effect-mediated d-band center downshifting, (2) optimized compressive strain, and (3) regulated ∗OOH adsorption energetics. The structural-activity relationships established here provide practical strategies for fabricating hybrid catalysts with ultralow noble metal loading and enhanced CO tolerance. Such atomic-level insights not only guide the rational design of catalysts, but also facilitate the deployment of fuel cells in maritime propulsion systems and backup power units.

Original language	English
Article number	236772
Journal	Journal of Power Sources
Volume	640
DOIs	https://doi.org/10.1016/j.jpowsour.2025.236772
State	Published - 1 Jun 2025
Externally published	Yes

Keywords

Electrocatalysis
Fuel cells
Low-dimensional nanostructures
Synthesis methods

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.jpowsour.2025.236772

Cite this

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title = "Low-dimensional design of precious metal-based catalysts in fuel cells",

abstract = "The development of low-dimensional noble metal catalysts has emerged as a critical pathway to address the cost-durability challenges in fuel cells. This review synthesizes recent advances in designing ultrathin nanowires, defect-engineered metalene, and strain-tuned nanosheets that demonstrate exceptional oxygen reduction SSreaction activity and cycling stability. We systematically decode three atomic-level enhancement mechanisms: (1) ligand effect-mediated d-band center downshifting, (2) optimized compressive strain, and (3) regulated ∗OOH adsorption energetics. The structural-activity relationships established here provide practical strategies for fabricating hybrid catalysts with ultralow noble metal loading and enhanced CO tolerance. Such atomic-level insights not only guide the rational design of catalysts, but also facilitate the deployment of fuel cells in maritime propulsion systems and backup power units.",

keywords = "Electrocatalysis, Fuel cells, Low-dimensional nanostructures, Synthesis methods",

author = "Peixi Qiu and Chengyong Shu and Zhoufan Gan and Jingwen Cao and Zhixu Chen and Hao Wu and Yuping Wu and Wei Tang",

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doi = "10.1016/j.jpowsour.2025.236772",

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T1 - Low-dimensional design of precious metal-based catalysts in fuel cells

AU - Qiu, Peixi

AU - Shu, Chengyong

AU - Gan, Zhoufan

AU - Cao, Jingwen

AU - Chen, Zhixu

AU - Wu, Hao

AU - Wu, Yuping

AU - Tang, Wei

PY - 2025/6/1

Y1 - 2025/6/1

N2 - The development of low-dimensional noble metal catalysts has emerged as a critical pathway to address the cost-durability challenges in fuel cells. This review synthesizes recent advances in designing ultrathin nanowires, defect-engineered metalene, and strain-tuned nanosheets that demonstrate exceptional oxygen reduction SSreaction activity and cycling stability. We systematically decode three atomic-level enhancement mechanisms: (1) ligand effect-mediated d-band center downshifting, (2) optimized compressive strain, and (3) regulated ∗OOH adsorption energetics. The structural-activity relationships established here provide practical strategies for fabricating hybrid catalysts with ultralow noble metal loading and enhanced CO tolerance. Such atomic-level insights not only guide the rational design of catalysts, but also facilitate the deployment of fuel cells in maritime propulsion systems and backup power units.

AB - The development of low-dimensional noble metal catalysts has emerged as a critical pathway to address the cost-durability challenges in fuel cells. This review synthesizes recent advances in designing ultrathin nanowires, defect-engineered metalene, and strain-tuned nanosheets that demonstrate exceptional oxygen reduction SSreaction activity and cycling stability. We systematically decode three atomic-level enhancement mechanisms: (1) ligand effect-mediated d-band center downshifting, (2) optimized compressive strain, and (3) regulated ∗OOH adsorption energetics. The structural-activity relationships established here provide practical strategies for fabricating hybrid catalysts with ultralow noble metal loading and enhanced CO tolerance. Such atomic-level insights not only guide the rational design of catalysts, but also facilitate the deployment of fuel cells in maritime propulsion systems and backup power units.

KW - Electrocatalysis

KW - Fuel cells

KW - Low-dimensional nanostructures

KW - Synthesis methods

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DO - 10.1016/j.jpowsour.2025.236772

M3 - 文献综述

AN - SCOPUS:86000768758

SN - 0378-7753

VL - 640

JO - Journal of Power Sources

JF - Journal of Power Sources

M1 - 236772

ER -

Low-dimensional design of precious metal-based catalysts in fuel cells

Abstract

Keywords

UN SDGs

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