锐钛矿
面(心理学)
材料科学
电解质
化学工程
离子
纳米晶
吸附
扩散
纳米技术
化学
物理化学
光催化
催化作用
电极
有机化学
心理学
社会心理学
人格
工程类
五大性格特征
热力学
物理
作者
Rong Li,Liuyan Xia,Jili Yue,Junhan Wu,Xuxi Teng,Jun Chen,Guangsheng Huang,Jingfeng Wang,Fusheng Pan
标识
DOI:10.1007/s40820-025-01861-7
摘要
Abstract Micro-sized anatase TiO 2 displays inferior capacity as cathode material for magnesium ion batteries because of the higher diffusion energy barrier of Mg 2+ in anatase TiO 2 lattice. Herein, we report that nanosized anatase TiO 2 exposed (001) facet doubles the capacity compared to the micro-sized sample ascribed to the interfacial Mg 2+ ion storage. First-principles calculations reveal that the diffusion energy barrier of Mg 2+ on the (001) facet is significantly lower than those in the bulk phase and on (100) facet, and the adsorption energy of Mg 2+ on the (001) facet is also considerably lower than that on (100) facet, which guarantees superior interfacial Mg 2+ storage of (001) facet. Moreover, anatase TiO 2 exposed (001) facet displays a significantly higher capacity of 312.9 mAh g −1 in Mg–Li dual-salt electrolyte compared to 234.3 mAh g −1 in Li salt electrolyte. The adsorption energies of Mg 2+ on (001) facet are much lower than the adsorption energies of Li + on (001) facet, implying that the Mg 2+ ion interfacial storage is more favorable. These results highlight that controlling the crystal facet of the nanocrystals effectively enhances the interfacial storage of multivalent ions. This work offers valuable guidance for the rational design of high-capacity storage systems.
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