Production of Small-Scale Alfv\'en Waves by Ionospheric Depletion, Nonlinear Magnetosphere-Ionosphere Coupling and Phase Mixing

TL;DR

This paper proposes a new mechanism for the formation of small-scale Alfvén waves in the magnetosphere-ionosphere system, emphasizing nonlinear ionospheric depletion and phase mixing over the traditional feedback instability explanation.

Contribution

It introduces a novel interpretation that attributes small-scale Alfvén wave generation to nonlinear ionospheric depletion and wavebreaking, excluding the feedback instability as the primary cause.

Findings

Waves match observed periods under realistic conditions.

Wavelengths shorten over time due to phase mixing.

Mechanism can seed ionospheric feedback instability.

Abstract

Rockets and satellites have previously observed small-scale Alfv\'en waves inside large-scale downward field-aligned currents and numerical simulations have associated their formation with self-consistent magnetosphere-ionosphere coupling. The origin of these waves was previously attributed to ionospheric feedback instability, however we show that they arise in numerical experiments in which the instability is excluded. A new interpretation is proposed in which strong ionospheric depletion and associated current broadening (a nonlinear steepening/wavebreaking process) form magnetosphere-ionosphere waves inside a downward current region and these oscillations drive upgoing inertial Alfv\'en waves in the overlying plasma. The resulting waves are governed by characteristic periods, which are a good match to previously observed periods for reasonable assumed conditions. Meanwhile, wavelengths perpendicular to the magnetic field initially map to an ionospheric scale comparable to the electron inertial length for the low-altitude magnetosphere, but become shorter with time due to frequency-based phase mixing of boundary waves (a new manifestation of phase mixing). Under suitable conditions, these could act as seeds for the ionospheric feedback instability.