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Stable Metallicity of Low Dimentional WCrC Derivatives: A First‐Principles Study
Author(s) -
Liu Guogang,
Chen Tong,
Xu Liang,
Dong Xiansheng,
Cen Kangwei,
Zhu Yuyuan,
Xu Zhonghui,
Xiao Xianbo
Publication year - 2021
Publication title -
advanced theory and simulations
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.068
H-Index - 17
ISSN - 2513-0390
DOI - 10.1002/adts.202100036
Subject(s) - monolayer , metallicity , spintronics , mxenes , materials science , band gap , condensed matter physics , metal , atom (system on chip) , carbide , chemical physics , nanotechnology , ferromagnetism , chemistry , composite material , optoelectronics , physics , metallurgy , stars , astronomy , computer science , embedded system
The rapid development of 2D material MXenes family brings new opportunities for the application and development of materials science. Here, the structural and electronic properties of WCrC monolayer and its nanoribbons, and the effects of add‐atom adsorption in combination with strain engineering are presented by using first‐principles calculation. The result reveals that pristine WCrC monolayer is always dynamically stable and exhibits metallicity. Within a certain coverage range, the metallic WCrC monolayer can be transformed into semi‐metallic WCrCO 2 with dual narrow band gap by adsorbing O atoms, but adsorbed H and Cl atoms cannot change its metal behavior. Moreover, the spin‐splitting of WCrC monolayer is obvious, but when the compressive strain increases to 8%, the energy bands of WCrC monolayer achieve a singular behavior of spin degeneracy. However, neither compressive strain nor tensile strain changes the metallicity of WCrC monolayer. Meanwhile, WCrC nanoribbons with diverse boundaries configurations and edge‐terminated atoms are all metallic, which indicates that boundary configurations and edge‐terminated atoms are not the key factors affecting the metallicity of WCrC nanoribbons. These results suggest that WCrC derivatives are mainly metallic materials, which are expected to be applied in the field of spintronics and may provide new opportunities for the development of metal ion battery electrodes.

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