H2 Energetics in Galaxy-wide Shocks: Insights in Starburst Triggering and Galaxy Formation

TL;DR

This paper investigates galaxy-wide shocks using observations of molecular hydrogen (H2) emission, revealing its significant role in interstellar medium cooling, galaxy formation, and the complex relationship between H2 and star formation.

Contribution

It provides a physical framework for understanding H2 formation and emission in galaxy shocks, highlighting the importance of turbulence and energy transfer in these processes.

Findings

H2 emission exceeds X-ray emission in galaxy shocks

Most shock energy is transferred to H2 gas kinetic energy

Turbulent energy drives H2 formation from hot/warm gas

Abstract

Spitzer space telescope observations led to the surprising detection of a diverse set of extragalactic sources whose infrared spectra are dominated by line emission of molecular hydrogen (H2). The absence or relative weakness of typical signs of star formation (like dust features, lines of ionized gas) suggest the presence of large quantities of H2 gas with no (or very little) associated star formation. We use the Stephan's Quintet (SQ) galaxy collision to define a physical framework to describe the H2 formation and emission in galaxy-wide shocks. SQ observations show that exceptionally turbulent H2 gas is coexisting with a hot, X-ray emitting plasma. The extreme mid-IR H2 emission from the shock exceeds that of the X-rays. These observations set a new light on the contribution of H2 to the cooling of the interstellar medium, on the relation between molecular gas and star formation, and on the energetics of galaxy formation. These observations can be interpreted by considering that the shock is moving through an inhomogeneous medium. They suggest that most of the shock energy is transferred to bulk kinetic energy of the H2 gas. The turbulent energy of the post-shock gas drives a mass cycle across the different gas phases where H2 is forming out of the hot/warm gas. This interpretation puts the H2 emission into a broader context including optical and X-ray observations. We propose that the turbulence in the clouds is powered by a slow energy and momentum transfer from the bulk motion of the gas and that the dissipation of this turbulent energy in turn is powering the H2 emission.