材料科学
非阻塞I/O
电解质
化学工程
电化学
微观结构
高温电解
电极
烧结
陶瓷
粒径
氢
氧化物
粒子(生态学)
氧化镍
纳米颗粒
纳米技术
制氢
可逆氢电极
欧姆接触
电化学电池
析氧
合金
电催化剂
镍
作者
Yuchen Zhang,Zeyu Zhao,Quanwen Sun,Meng Li,Hao Deng,Wenjuan Bian,Jianhua Tong,Dong Ding
出处
期刊:Small
[Wiley]
日期:2026-05-15
卷期号:: e73740-e73740
摘要
ABSTRACT Protonic ceramic electrochemical cells (PCECs) operating at intermediate temperatures (400–600°C) enable efficient hydrogen production, power generation, and chemical synthesis. To enhance electrochemical performance, engineering the electrode‐electrolyte interface is an effective approach. While substantial progress has been achieved at the oxygen electrode/electrolyte interface, understanding of the hydrogen electrode/electrolyte interface, particularly involving hydrogen electrode functional layers (HEFLs), remains limited. This study investigated the effects of nickel oxide (NiO) particle size in HEFLs on microstructural evolution and electrochemical behavior. HEFLs fabricated with smaller NiO particles enhanced electrolyte membrane densification and promoted more homogeneous and fine‐grained localized microstructures after reduction. These improvements in nano‐NiO samples reduced ohmic resistance from 0.23 Ω cm 2 to ≈0.15 Ω cm 2 , at 600°C, yielding a peak power density, 1.11 W cm −2 (fuel cell) and a current density, −1.50 A cm −2 at 1.3 V with 30% steam (electrolysis). Findings reveal clear relationship that initial NiO particle size influences the thin electrolyte sintering and localized microstructure evolution, consequently affecting gas diffusion and electrochemical interfaces, and ultimately electrochemical performance of PCECs. This work provides fundamental insights into interface and functional layer engineering, offering guidance for the rational design of optimized PCEC architectures with enhanced electrochemical performance.
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