Tailored Design of Iridium Single Atoms on Mn–Ni‐Phytate with Robust Bifunctionality for Enhanced Anion Exchange Membrane Water Electrolysis

双功能 析氧 材料科学 催化作用 双功能催化剂 分解水 化学工程 氢氧化物 电解 电催化剂 电解水 碱性水电解 离子交换 制氢 密度泛函理论 法拉第效率 电化学 无机化学 过电位 纳米技术 电极 离子 热液循环 膜电极组件 制作 Pourbaix图
作者
Quynh Phuong Ngo,Sae Yane Paek,Jun Young Lee,Ho Ngoc Nam,Quan Manh Phung,Thanh Hai Nguyen,Jin Young Seo,Yusuke Yamauchi,Le Hoang Sinh,Yun Jung Lee,Jong Min Kim,Jongbeom Na
出处
期刊:Advanced Energy Materials [Wiley]
卷期号:16 (11) 被引量:6
标识
DOI:10.1002/aenm.202506645
摘要

ABSTRACT The development of efficient and durable bifunctional electrocatalysts is essential to simplify electrode design and fabrication in anion exchange membrane water electrolyzers (AEMWEs). However, most existing bifunctional catalysts suffer from poor stability and struggle to achieve high activity for both the hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) simultaneously. Herein, we report Ir@Mn–Ni‐PA, phytic acid‐modified Mn‐doped Ni layered double hydroxide catalyst that incorporates atomically dispersed Ir sites through tailored design of single atoms. Synthesized via a simple hydrothermal method, the catalyst features hierarchical nanoarrays that enhance electron transport, mass diffusion, and hydrophilicity. Ir@Mn–Ni‐PA exhibits excellent bifunctional activity, delivering low overpotentials of 65 mV for HER and 272 mV for OER at 10 mA cm −2 , along with stability exceeding 100 h. When implemented in an AEMWE cell, it achieves a high current density of 1.64 A cm −2 at 2.0 V and remains stable for 300 h under industrially relevant conditions. Density functional theory calculations reveal that Ir atoms modulate the Mn–Ni‐PA electronic structure, narrowing the bandgap and enhancing charge transfer, which improves water adsorption, dissociation, and catalytic activity. These results highlight the potential of atomic‐level engineering for designing durable, high‐performance bifunctional catalysts for sustainable energy conversion.
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