English

Terahertz Optics Driven Phase Transition in Two-Dimensional Multiferroics

Materials Science 2021-01-26 v1

Abstract

Displacive martensitic phase transition is potentially promising in semiconductor based data storage applications with fast switching speed. In addition to traditional phase transition materials, the recently discovered two-dimensional ferroic materials are receiving lots of attention owing to their fast ferroic switching dynamics, which could tremendously boost data storage density and enhance read/write speed. In this study, we propose that a terahertz laser with an intermediate intensity and selected frequency can trigger ferroic order switching in two-dimensional multiferroics, which is a damage-free noncontacting approach. Through first-principles calculations, we theoretically and computationally investigate optically induced electronic, phononic, and mechanical responses of two experimentally fabricated multiferroic (with both ferroelastic and ferroelectric) materials, \b{eta}-GeSe and {\alpha}-SnTe monolayer. We show that the relative stability of different orientation variants can be effectively manipulated via the polarization direction of the terahertz laser, which is selectively and strongly coupled with the transverse optical phonon modes. The transition from one orientation variant to another can be barrierless, indicating ultrafast transition kinetics and the conventional nucleation-growth phase transition process can be avoidable.

Keywords

Cite

@article{arxiv.2011.14290,
  title  = {Terahertz Optics Driven Phase Transition in Two-Dimensional Multiferroics},
  author = {Jian Zhou and Shunhong Zhang},
  journal= {arXiv preprint arXiv:2011.14290},
  year   = {2021}
}

Comments

To appear in npj 2D Materials and Applications

R2 v1 2026-06-23T20:34:33.020Z