Ubiquitous Instabilities of Dust Moving in Magnetized Gas

TL;DR

This paper demonstrates that dust moving in magnetized gas universally exhibits instabilities driven by resonances with MHD waves and Lorentz forces, with growth rates weakly dependent on physical parameters, across various astrophysical environments.

Contribution

It extends the theory of resonant drag instabilities to include magnetic fields and charged dust, revealing new instability families and behaviors in magnetized astrophysical gases.

Findings

Dust-gas mixtures are always unstable under magnetic fields.

New instability families arise due to magnetic fields and dust charge.

Growth rates depend weakly on physical parameters and can grow unbounded.

Abstract

Squire & Hopkins (2017) showed that coupled dust-gas mixtures are generically subject to 'resonant drag instabilities' (RDIs), which drive violently-growing fluctuations in both. But the role of magnetic fields and charged dust has not yet been studied. We therefore explore the RDI in gas which obeys ideal MHD and is coupled to dust via both Lorentz forces and drag, with an external acceleration (e.g., gravity, radiation) driving dust drift through gas. We show this is always unstable, at all wavelengths and non-zero values of dust-to-gas ratio, drift velocity, dust charge, 'stopping time' or drag coefficient (for any drag law), or field strength; moreover growth rates depend only weakly (sub-linearly) on these parameters. Dust charge and magnetic fields do not suppress instabilities, but give rise to a large number of new instability 'families,' each with distinct behavior. The 'MHD-wave' (magnetosonic or Alfven) RDIs exhibit maximal growth along 'resonant' angles where the modes have a phase velocity matching the corresponding MHD wave, and growth rates increase without limit with wavenumber. The 'gyro' RDIs are driven by resonances between drift and Larmor frequencies, giving growth rates sharply peaked at specific wavelengths. Other instabilities include 'acoustic' and 'pressure-free' modes (previously studied), and a family akin to cosmic ray instabilities which appear when Lorentz forces are strong and dust streams super-Alfvenically along field lines. We discuss astrophysical applications in the warm ISM, CGM/IGM, HII regions, SNe ejecta/remnants, Solar corona, cool-star winds, GMCs, and AGN.