Materials Science and Engineering

Biography

Biography: Yuma Nakamura

Abstract

Among two-dimensional materials, group IV elemental sheets such as graphene, silicene, germanene and stanene have been intensively investigated using first principles calculation. We look at the intrinsic carrier mobility for stanene, or the tin-monolayer, using Boltzmann transport equation coupled with density functional perturbation theory plus Wannier interpolation approximation to consider electron scattering with all the phonon branches with dispersion contribution. It is found that the conventional deformation potential (DP) approach which worked well for many layered materials, can well overestimate the carrier mobility in stanene because the buckled structure allows more types of electron-phonon scattering, such as acoustic flexural mode. DP theory assumed that only longitudinal acoustic phonon in long wavelength limit (|q|∼0) contributes to the charge relaxation process. In this work, we calculate all phonon modes, such as out-of-plane acoustic mode, transverse acoustic mode, and optical counterparts, in addition to longitudinal acoustic mode, plus dispersion effects and we investigate the intrinsic carrier mobility, in comparison with the DP theory. We find that the intrinsic carrier mobility could be as high as 2~3x10⁶ cm² V⁻¹ s⁻¹ by DP theory but becomes only 2~3x103 cm² V⁻¹ s⁻¹ by the full evaluation of electron-phonon coupling. It is found that the intervalley scattering process in acoustic out-of-plane and transverse mode, which DP ignored dominate the carrier relaxation.

Recent Publications:

1. Yuma Nakamura, Tianqi Zhao, Jinyang Xi, Wen Shi, Dong Wang, Zhigang Shuai (2017) Intrinsic Charge Transport in Stanene: Roles of Bucklings and Electron-Phonon Couplings. Computational Physics