Prediction of Intriguing Valley Properties in Two-Dimensional Hf2TeIX (X = I, Br) Monolayers

IF 2.4 4区材料科学 Q2 CRYSTALLOGRAPHY

Crystals Pub Date : 2024-09-09 DOI:10.3390/cryst14090794

Kaiyuan He, Peiji Wang

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引用次数: 0

Abstract

The valley degree of freedom, as a new information carrier, is important for basic physical research and the development of advanced devices. Herein, using first-principle calculations, we predict that two-dimensional Hf2TeIX (X = I, Br) monolayers harbor intriguing valley properties. Without considering spin–orbit coupling (SOC), the Hf2TeI2 monolayer has a semi-metallic nature, with Dirac cones located at the high-symmetry point K, and feature, with considerable Fermi velocity. When the SOC is taken into account, a band gap opening of 271 meV can be observed at the Dirac cones. More interestingly, the Hf2TeIBr monolayer exhibits intrinsic spatial inversion symmetry breaking, which leads to the emergence of valley-contrasting physics under SOC. This is demonstrated by the presence of spin–valley splitting and opposite Berry curvature at adjacent K points. Besides, the spin–valley splitting, the band gap and magnitude of the Berry curvature of the Hf2TeIBr monolayer can be effectively tuned by strain engineering. These findings contribute significantly to the design of valleytronic devices and extend opportunities for exploring two-dimensional valley materials.

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预测二维 Hf2TeIX（X = I，Br）单层中的迷人谷特性

谷自由度作为一种新的信息载体，对基础物理研究和先进设备的开发具有重要意义。在此，我们利用第一原理计算，预测二维 Hf2TeIX（X = I，Br）单层蕴藏着引人入胜的谷特性。在不考虑自旋轨道耦合（SOC）的情况下，Hf2TeI2 单层具有半金属性质，其狄拉克锥位于高对称点 K，并具有相当大的费米速度特征。当考虑到 SOC 时，可以在狄拉克锥处观察到 271 meV 的带隙开口。更有趣的是，Hf2TeIBr 单层显示出内在的空间反转对称性破坏，这导致了在 SOC 作用下出现了山谷对比物理学。相邻 K 点出现的自旋谷分裂和相反的贝里曲率证明了这一点。此外，Hf2TeIBr 单层的自旋谷分裂、带隙和贝里曲率的大小可以通过应变工程进行有效调节。这些发现极大地促进了谷电子器件的设计，并拓展了探索二维谷材料的机会。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Crystals CRYSTALLOGRAPHYMATERIALS SCIENCE, MULTIDIS-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

4.20

自引率

11.10%

发文量

1527

审稿时长

16.12 days

期刊介绍： Crystals (ISSN 2073-4352) is an open access journal that covers all aspects of crystalline material research. Crystals can act as a reference, and as a publication resource, to the community. It publishes reviews, regular research articles, and short communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on article length. Full experimental details must be provided to enable the results to be reproduced. Crystals provides a forum for the advancement of our understanding of the nucleation, growth, processing, and characterization of crystalline materials. Their mechanical, chemical, electronic, magnetic, and optical properties, and their diverse applications, are all considered to be of importance.