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Hardening tungsten carbide by alloying elements with high work function
Author(s) -
Lu Hao,
Zhao Chong,
Wang Haibin,
Liu Xuemei,
Yu Rong,
Song Xiaoyan
Publication year - 2019
Publication title -
acta crystallographica section b
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.604
H-Index - 33
ISSN - 2052-5206
DOI - 10.1107/s2052520619012277
Subject(s) - tungsten carbide , tungsten , materials science , carbide , work function , metallurgy , refractory metals , hardening (computing) , tungsten compounds , metal , composite material , layer (electronics)
There is intensive searching for superhard materials in both theoretical and experimental studies. Refractory and transition metal carbides are typical materials with high hardness. In this study, first‐principles calculations were performed first to analyze the electronic structures and mechanical properties of the tungsten‐carbide‐based compounds. The results indicated that tungsten carbide could be hardened by alloying elements with high work functions to tailor the Fermi level and electron density. Guided by the calculations, a new type of tungsten carbide alloyed with Re was synthesized. The Young's modulus and hardness of the Re‐alloyed tungsten carbide are increased by 31% and 44%, respectively, as compared with those of tungsten carbide. This study provides a new methodology to design superhard materials on a feasible electronic base using work function as a simple guiding parameter.