Giant capacitance of a plane capacitor with a two-dimensional electron gas in a magnetic field

Abstract

If a clean two-dimensional electron gas (2DEG) with small concentration n comprises one (or both) electrodes of a plane capacitor, the resulting capacitance C can be larger than the "geometric capacitance" Cg determined by the physical separation d between electrodes. A recent paper [1] argued that when the effective Bohr radius aB of the 2DEG satisfies aB << d, one can achieve C >> Cg at low concentration nd2 << 1. Here we show that even for devices with aB > d, including graphene, for which aB is effectively infinite, one also arrives at C >> Cg at low electron concentration if there is a strong perpendicular magnetic field.