Kelvin-Mach wake in a two-dimensional Fermi sea

TL;DR

This paper investigates the wake patterns generated by a charged impurity in a two-dimensional electron gas with plasma oscillations, revealing a transition from Mach to Kelvin-like wakes as the Mach number increases.

Contribution

It introduces the discovery of Kelvin-Mach wakes in a 2D Fermi sea, showing how wake geometry changes with the Mach number and identifying a Kelvin-like wake beyond a critical Mach number.

Findings

Wake pattern transitions from Mach to Kelvin-like as M exceeds √2

Wake angles are determined by the Mach number and plasma dispersion law

External charge traveling supersonically creates similar wake structures

Abstract

The dispersion law for plasma oscillations in a two-dimensional electron gas in the hydrodynamic approximation interpolates between $\Omega \propto \sqrt{q}$ and $\Omega \propto q$ dependences as the wave vector $q$ increases. As a result, downstream of a charged impurity in the presence of a uniform supersonic electric current flow, a wake pattern of induced charge density and potential is formed whose geometry is controlled by the Mach number $M$. For $1<M\leqslant \sqrt{2}$ the wake consists of transverse wavefronts confined within a sector whose angle is given by the classic Mach condition. An additional wake of larger angle resembling the Kelvin ship wake and consistsing of both transverse and diverging wavefronts is found outside the Mach sector for $M>\sqrt{2}$. These wakes also trail an external charge traveling supersonically a fixed distance away from the electron gas.