English

Valley-engineering mobilities in two-dimensional materials

Materials Science 2019-05-30 v2

Abstract

Two-dimensional materials are emerging as a promising platform for ultrathin channels in field-effect transistors. To this aim, novel high-mobility semiconductors need to be found or engineered. While extrinsic mechanisms can in general be minimized by improving fabrication processes, the suppression of intrinsic scattering (driven e.g. by electron-phonon interactions) requires to modify the electronic or vibrational properties of the material. Since intervalley scattering critically affects mobilities, a powerful approach to enhance transport performance relies on engineering the valley structure. We show here the power of this strategy using uniaxial strain to lift degeneracies and suppress scattering into entire valleys, dramatically improving performance. This is shown in detail for arsenene, where a 2% strain stops scattering into 4 of the 6 valleys, and leads to a 600% increase in mobility. The mechanism is general and can be applied to many other materials, including in particular the isostructural antimonene and blue phosphorene.

Keywords

Cite

@article{arxiv.1902.11209,
  title  = {Valley-engineering mobilities in two-dimensional materials},
  author = {Thibault Sohier and Marco Gibertini and Davide Campi and Giovanni Pizzi and Nicola Marzari},
  journal= {arXiv preprint arXiv:1902.11209},
  year   = {2019}
}

Comments

14 pages, 14 figures

R2 v1 2026-06-23T07:54:29.393Z