Dyakonov-Shur instability of electronic fluid: Spectral effect of weak magnetic field

We study numerically and analytically how the Dyakonov-Shur instability for a two-dimensional (2D) inviscid electronic fluid in a long channel can be affected by an external, out-of-plane static magnetic field. By linear stability analysis for a model based on the shallow-water equations, we describe the discrete spectrum of frequencies in the complex plane. When the fluid system is near the subsonic-to-supersonic transition point, a magnetically controlled gap between the stability and instability spectra of the complex eigen-frequencies is evident by our computations. This suggests that the passage from stability to instability (and vice versa) is no longer continuous in the effective Mach parameter of the boundary conditions. We connect this complex-valued gap to a multivalued function characterizing the exact electronic steady state. In a regime of weak magnetic fields, we derive a scaling law for the eigen-frequencies by perturbation theory. We discuss implications of our results in efforts to generate terahertz electromagnetic radiation by 2D electronic transport.

Dyakonov-Shur instability of electronic fluid: Spectral effect of weak magnetic field Institutional Repository Document