English

Crystal valley Hall effect

Materials Science 2025-03-13 v2

Abstract

The time-reversal symmetry is thought to be a necessary condition for realizing valley Hall effect. If the time-reversal symmetry is broken, whether the valley Hall effect can be realized has not been explored. In this letter, based on symmetry analysis and the first-principles electronic structure calculations, we demonstrate that the vally Hall effect without time-reversal symmetry can be realized in two-dimensional altermagnetic materials Fe2_2WSe4_4 and Fe2_2WS4_4. Due to crystal symmetry required, the vally Hall effect without time-reversal symmetry is called crystal vally Hall effect. In addition, under uniaxial strain, both monolayer Fe2_2WSe4_4 and Fe2_2WS4_4 can realize piezomagnetic effect. Under biaxial compressive stress, both monolayer Fe2_2WSe4_4 and Fe2_2WS4_4 will transform from altermagnetic semiconductor phase to bipolarized topological Weyl semimetal phase. Our work not only provides a new direction for exploring the novel valley Hall effect, but also provides a good platform for exploring altermagnetic semiconductors and altermagnetic topological phase transitions.

Cite

@article{arxiv.2410.00073,
  title  = {Crystal valley Hall effect},
  author = {Chao-Yang Tan and Ze-Feng Gao and Huan-Cheng Yang and Zheng-Xin Liu and Kai Liu and Peng-Jie Guo and Zhong-Yi Lu},
  journal= {arXiv preprint arXiv:2410.00073},
  year   = {2025}
}

Comments

6 pages,4 figures

R2 v1 2026-06-28T19:02:52.182Z