Collaborative activation mechanism in double transition metal MXenes anode: An effective method to improve the capacitance of sodium ion battery

MXenes公司 阳极 电容 电负性 金属 过渡金属 材料科学 电子 化学物理 吸附 电池(电) 化学 化学工程 纳米技术 热力学 物理化学 冶金 电极 物理 工程类 有机化学 功率(物理) 催化作用 量子力学 生物化学
作者
Min Zhou,Yanqing Shen,Jiajia Liu,Lingling Lv,Yu Zhang,Xianghui Meng,Xin Yang,Bing Zhang,Zhongxiang Zhou
出处
期刊:Vacuum [Elsevier BV]
卷期号:213: 112150-112150 被引量:13
标识
DOI:10.1016/j.vacuum.2023.112150
摘要

Through theoretical calculations, it is found that anode materials with double transition metal terminals (VNbC, VTaC, and NbTaC) exhibit better performance than their single metallic phases. Compared with single metal phase, the maximum sodium adsorption capacities of VNbC, VTaC, and NbTaC increased by 75%, 37.5%, and 75%, respectively. In particular, the metal VNbC VTaC and NbTaC anodes not only have high theoretical capacitances of 601.85, 302.20 and 328.13 mAhg−1, but also have original low migration barriers with sodium atoms. Bader charge indicates that the large capacities originate from the difference in metal electronegativity, and this difference leads to a reduction in the charge contribution of transition metals in materials and the accumulation of excess electrons on the surface. These extra accumulated electrons can be transferred to the outside to form an additional negative electron cloud that stabilizes the formation of the second layer of sodium adsorption, and leading to a large theoretical capacitance. We named this phenomenon the “Collaborative Activation” mechanism of double transition metal MXenes. These interesting results show that MXene anodes composed of different metal terminals are powerful methods to improve anode performance. Therefore, it provides a powerful reference for the research of MXenes.
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