材料科学
氢气储存
氢化物
化学工程
计算机科学
工艺工程
氢
化学
金属
冶金
工程类
合金
有机化学
作者
Panpan Zhou,Qianwen Zhou,Wenzhe Liu,Nuo Lei,Yongpeng Chen,Jinghua Jiang,Dan Song,Haiwen Li,Qin‐Yi Li,Lixin Chen,Xuezhang Xiao
标识
DOI:10.1002/advs.202513463
摘要
MPEA achieves a breakthrough saturation capacity of 2.06 wt.% at 20 °C with merely 1.6 MPa electrolysis-derived hydrogen pressure. More significantly, this material maintains an exceptional reversible capacity of 1.93 wt.% at 80 °C (against 0.1 MPa back pressure), achieving an 93.7% capacity utilization efficiency. Such outstanding performance under limited operating conditions surpasses the vast majority of known C14 Laves-phase materials. Equally noteworthy is the superior structural-property robustness enabled by local strain release through timely pulverization during repeated hydrogen insertion/extraction, which results in negligible influence in hydrogen storage properties, crystallographic structure, or elemental distribution throughout extended cycling. These findings establish new design guidelines for high-capacity, long-cycle-life, low-cost hydrogen storage materials operating under energy-efficient conditions.
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