Berry curvature dipole and its strain engineering in layered phosphorene

Materials Today Electronics Pub Date : 2023-11-08 DOI:10.1016/j.mtelec.2023.100076

Arka Bandyopadhyay, Nesta Benno Joseph, Awadhesh Narayan

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Abstract

The emergence of the fascinating non-linear Hall effect intrinsically depends on the non-zero value of the Berry curvature dipole. In this work, we predict that suitable strain engineering in layered van der Waals material phosphorene can give rise to a significantly large Berry curvature dipole. Using symmetry design principles, and a combination of feasible strain and staggered on-site potentials, we show how a substantial Berry curvature dipole may be engineered at the Fermi level. We discover that monolayer phosphorene exhibits the most intense Berry curvature dipole peak near 11.8% strain, which is also a critical point for the topological phase transition in pristine phosphorene. Furthermore, we have shown that the necessary strain value to achieve substantial Berry curvature dipole can be reduced by increasing the number of layers. We have revealed that strain in these van der Waals systems not only alters the magnitude of Berry curvature dipole to a significant value but allows control over its sign. We are hopeful that our predictions will pave way to realize the non-linear Hall effect in such elemental van der Waals systems.

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层状磷烯中的Berry曲率偶极子及其应变工程

迷人的非线性霍尔效应的出现本质上依赖于贝里曲率偶极子的非零值。在这项工作中，我们预测在层状范德瓦尔斯材料磷烯中适当的应变工程可以产生显着大的Berry曲率偶极子。利用对称设计原理，结合可行应变和交错位势，我们展示了如何在费米能级上设计一个实质性的贝里曲率偶极子。我们发现单层磷烯在11.8%应变附近呈现出最强烈的Berry曲率偶极子峰，这也是原始磷烯拓扑相变的临界点。此外，我们已经表明，必要的应变值，以实现实质性的贝里曲率偶极子可以通过增加层数来降低。我们揭示了这些范德华体系中的应变不仅使贝里曲率偶极子的大小改变到一个显著的值，而且可以控制它的符号。我们希望我们的预测将为在这些元素范德华体系中实现非线性霍尔效应铺平道路。

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

Materials Today Electronics

CiteScore

2.10

自引率

0.00%

发文量