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最近,将高熵引入各种用于不同应用的材料引起了研究人员的兴趣越来越大,并促进了一系列单相多层(等极)材料的快速发展。[1-4]在无序的多组分系统中,大型构型熵被认为可以稳定晶体结构,从而传递高渗透效果(HE)效应,即,熵驱动的施加效果以及相关的“鸡尾酒”效应由阳离子混合以及化学和结构多样性产生。[1,4,5] Within the past few years, a large number of high-entropy materials (HEMs), represented first by high-entropy alloys (HEAs) [1,5–8] and later by high- entropy oxides (HEOs), [3,9–13] have been utilized in a broad range of applications, including environmental protection, elec- trochemical energy storage, and thermo- electric and catalytic applications.在电池材料中,最近的几份报告表明,高熵的引入可以大大改善循环性能,例如,在HEO和高渗透氧气中(HEOFS)。[9,10,14–24] In a previous study by our group, rock-salt (Co 0.2 Cu 0.2 Mg 0.2 Ni 0.2 Zn 0.2 )O was proposed as a promising anode material for lithium-ion batteries (LIBs), with a unique entropy- stabilized Li-storage mechanism, guaranteeing the reversible conversion reaction and leading to improved cycling stability and Coulombic efficiency.[25,26]另一个针对电化学应用的限制是,据报道,HEO在电化学循环期间会经历不利的相位,这可以使其成为[9]此外,HU和同事在层状O3型HEO上报道了钠离子电池(SIBS)的互嵌型阴极[10],表现出良好的长期可环性和速率性能,并促进宿主矩阵的熵稳定。然而,高注册材料的缺点是它们的制备通常涉及具有高能量成本的程序,例如(高能量)球磨碎或高温处理(> 900°C),并且可以容易容易出现相位分离(例如,对于多物质纳米属粒子)。
高度可逆钠储存的高渗透金属 - 有机框架
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