普鲁士蓝
阳极
阴极
氧化还原
水溶液
化学
离子
溶解
扩散
拉曼光谱
无机化学
电化学储能
储能
限制
化学工程
金属
水溶液中的金属离子
纳米技术
容量损失
过渡金属
材料科学
动力学
电化学
电极
作者
Hao Fu,Jun Yang,Zhiqiang Wu,Ren He,Jianeng Ji,Chunyan Li,Minjie Shi,Edison Huixiang Ang
标识
DOI:10.1016/j.jcis.2025.139331
摘要
Manganese-based Prussian blue analogues (Mn-PBA) have garnered significant attention due to their exceptionally high specific capacity in aqueous sodium-ion batteries (ASIBs). However, the dissolution of Mn2+ ions during the charge/discharge process leads to structural degradation, adversely affecting cycle life and limiting practical applications. In this work, a high-entropy strategy is employed to overcome this limitation. The resulting high-entropy Mn-PBA (HE-Mn-PBA), synthesized via a simple co-precipitation method, benefits from entropy stabilization and synergistic effects among multiple metal components, enabling excellent structural integrity during prolonged cycling. As a cathode material, HE-Mn-PBA achieves nearly 100 % capacity retention (116.07 mAh g-1) after 200 cycles at 1 A g-1, along with stable performance over 10,000 cycles. In situ Raman spectroscopy confirms the formation of enhanced and reversible redox-active centers, while kinetic analyses reveal significantly improved Na+ diffusion kinetics. Furthermore, a full cell assembled with a polyimide anode delivers a high energy density of 56.11 Wh kg-1. This high-entropy engineering approach offers a promising pathway to address the stability challenges of Mn-based materials in ASIBs.
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