Chenyang Zheng scite author profile

Anion exchange membrane fuel cells (AEMFCs) performance have significantly improved in the last decade (>1 W cm−2), and is now comparable with that of proton exchange membrane fuel cells (PEMFCs). At high current densities, issues in the catalyst layer (CL, composed of catalyst and ionomer), like oxygen transfer, water balance, and microstructural evolution, play important roles in the performance. In addition, CLs for AEMFCs have different requirements than for PEMFCs, such as chemical/physical stability, reaction mechanism, and mass transfer, because of different conductive media and pH environment. The anion exchange ionomer (AEI), which is the soluble or dispersed analogue of the anion exchange membrane (AEM), is required for hydroxide transport in the CL and is normally handled separately with the electrocatalyst during the electrode fabrication process. The importance of the AEI–catalyst interface in maximizing the utilization of electrocatalyst and fuel/oxygen transfer process must be carefully investigated. This review briefly covers new concepts in the complex AEMFC catalyst layer, before a detailed discussion on advances in CLs based on the design of AEIs and electrocatalysts. The importance of the structure–function relationship is highlighted with the aim of directing the further development of CLs for high‐performance AEMFC.

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Magnetic-field-oriented mixed-valence-stabilized ferrocenium anion-exchange membranes for fuel cells

Liu

Xie

Xue

et al. 2022

Nat Energy

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Oriented proton-conductive nano-sponge-facilitated polymer electrolyte membranes

Liu

Zhang

Zheng

et al. 2020

Energy Environ. Sci.

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Oil–Water–Oil Triphase Synthesis of Ionic Covalent Organic Framework Nanosheets

Guo

Jiang

et al. 2021

Angew Chem Int Ed

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Ionic covalent organic framework nanosheets (iCOFNs) with long-range ordered and mono-dispersed ionic groups hold great potential in many advanced applications. Considering the inherent drawbacks of oil-water biphase method, herein, we explore an oil-water-oil triphase method based on phase engineering strategy for the bottom-up synthesis of iCOFNs.The middle water phase serves as aconfined reaction region, and the two oil phases are reservoirs for storing and supplying monomers to the water phase.Alarge aqueous space and lowm onomer concentration lead to the anisotropic gradual growth of iCOFNs into few-layer thickness,l arge lateral size, and high crystallinity.N otably,t he resulting three cationic and anionic iCOFNs exhibit ultra-high aspect ratios of up to 20,000. We further demonstrate their application potential by processing into ultrathin defect-free COF membranes for efficient biogas separation. Our triphase method may offer an alternative platform technology for the synthesis and innovative applications of iCOFNs.

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Chenyang Zheng

Recent Insights on Catalyst Layers for Anion Exchange Membrane Fuel Cells

Magnetic-field-oriented mixed-valence-stabilized ferrocenium anion-exchange membranes for fuel cells

Oriented proton-conductive nano-sponge-facilitated polymer electrolyte membranes

Oil–Water–Oil Triphase Synthesis of Ionic Covalent Organic Framework Nanosheets

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