Anisotropy-driven quantum capacitance in multi-layered black phosphorus
Abstract
We report analytic results on quantum capacitance (C) measurements and their optical tuning in dual-gated device with potassium-doped multi-layered black phosphorous (BP) as the channel material. The two-dimensional (2D) layered BP is highly anisotropic with a semi-Dirac dispersion marked by linear and quadratic contributions. The C calculations mirror this asymmetric arrangement. A further increase to the asymmetry and consequently C is predicted by photon-dressing the BP dispersion. To achieve this and tune C in a field-effect transistor (FET), we suggest a configuration wherein a pair of electrostatic (top) and optical (back) gates clamp a BP channel. The back gate shines an optical pulse to rearrange the dispersion of the 2D BP. Analytic calculations are done with Floquet Hamiltonians in the off-resonant regime. The value of such C calculations, in addition, to its role in adjusting the current drive of an FET is discussed in context of metal-insulator and topological phase transitions and enhancements to the thermoelectric figure of merit.
Keywords
Cite
@article{arxiv.1708.02350,
title = {Anisotropy-driven quantum capacitance in multi-layered black phosphorus},
author = {Parijat Sengupta and Shaloo Rakheja},
journal= {arXiv preprint arXiv:1708.02350},
year = {2017}
}
Comments
4 pages, 3 figures