Unveiling transition metal dinitrides for high‐efficiency information devices through systematic first‐principles calculations

材料科学 过渡金属 纳米技术 工程物理 工程类 生物化学 化学 催化作用
作者
Junfei Ding,Qiushi Yao,Yunpeng Qu,Farid Manshaii,Shaolei Wang,Xiaosi Qi,Yao Liu
出处
期刊:Rare Metals [Springer Science+Business Media]
卷期号:44 (7): 4789-4800 被引量:3
标识
DOI:10.1007/s12598-024-03197-4
摘要

Abstract Currently, the development of high‐efficiency two‐dimensional (2D) transistors is still hindered by the limited availability of suitable semiconductors and the contact resistance between the metal contact and the 2D semiconductors. Endeavors to address these challenges are highly desired. In this study, we conducted a comprehensive exploration of the potential 2D transition metal dinitrides (TMN 2 s, TM = all the 3d, 4d and 5d transition metals) with hexagonal (h‐) and trigonal (t‐) phases through systematic first‐principles calculations. Among all h‐TMN 2 s and t‐TMN 2 s structures, we identified 8 TMN 2 s that exhibit dynamical and thermal stability at room temperature. Of these, the h–TiN 2 , h–ZrN 2 and h–HfN 2 are found to be semiconductors, and their direct bang gap, calculated at the HSE06 level, are 1.48, 1.96 and 2.64 eV, respectively. The electron and hole mobility ( μ e and μ h ) of these three structures exceed 1 × 10 4 and 1 × 10 3 cm 2 ·V −1 ·s −1 , respectively. Especially, the μ e of h–TiN 2 amounts to 2.5 × 10 4 cm 2 ·V −1 ·s −1 , and the μ h of h‐ZrN 2 reaches to 7.7 × 10 3 cm 2 ·V −1 ·s −1 . Importantly, unlike the MoS 2 system, h–TMN 2 forms Ohm contacts with both transition metals (e.g., Cu) and 2D metals (e.g., graphene), with tunneling possibilities exceeding 50% in the Cu system. These outstanding intrinsic semiconductor properties and contact characteristics exhibited by h–TMN 2 highlight the immense potential of transition metal dinitrides in driving the advancement of next‐generation information devices. Our findings significantly broaden the range of 2D materials and provide valuable insights for the development of high‐efficiency 2D information devices.
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