English

2D electrons floating on a suspended atomically thin dielectric

Mesoscale and Nanoscale Physics 2021-06-01 v2

Abstract

The 2D electrons trapped in vacuum near the atomically thin dielectric (ATD, mono- or NN-layer film of hh-BN or transition metal dichalcogenide) are considered. ATD is suspended above the back gate and forms the capacitor which is controlled by the biased voltage determining 2D concentration, n2Dn_{2D}. It is found that the leakage current through ATD is negligible and effect of the polarizability of ATD is weak if N5N\leq 5. At temperatures T=0.1÷T=0.1\div15 K and n2D=5×108÷1010n_{2D}=5\times 10^8\div 10^{10} cm2^{-2}, one deals with the Boltzmann liquid of the macroscopic thickness \sim100 A. Due to bending of ATD the quadratic dispersion law of the flexural vibrations is transformed into the linear one at small wave vectors. The scattering processes of the electrons caused by these phonons or the monolayer islands on ATD are examined and the momentum and energy relaxation rates are analyzed based on the corresponding balance equations. The momentum relaxation times varies over orders of magnitude in the above region (TT, n2Dn_{2D}) and NN. The response may changed from the polaron transport, for a perfect single-layer ATD at low TT and high n2Dn_{2D}, to the high-mobility (107\geq 10^7 cm2^2/Vs) regime at high TT and low n2Dn_{2D}. The quasi-elastic energy relaxation due to the phonon-induced scattering is considered and the conditions for heating of electrons by a weak in-plane electric field are found.

Keywords

Cite

@article{arxiv.2103.10424,
  title  = {2D electrons floating on a suspended atomically thin dielectric},
  author = {F. T. Vasko},
  journal= {arXiv preprint arXiv:2103.10424},
  year   = {2021}
}

Comments

12 pages, 6 figures

R2 v1 2026-06-24T00:19:43.884Z