Supernova feedback efficiency and mass loading in the starburst and galactic superwind exemplar M82

TL;DR

This study measures the efficiency of supernova feedback and the mass loading in M82's superwind using hydrodynamical models and X-ray observations, providing key parameters for galaxy evolution simulations.

Contribution

First direct measurement of feedback efficiency and mass-loading in a starburst galaxy using combined modeling and X-ray data.

Findings

Feedback efficiency is between 30% and 100%.

Mass loading factor is between 1.0 and 2.8.

Wind velocities exceed escape velocity, influencing galaxy evolution.

Abstract

We measure the net energy efficiency of supernova and stellar wind feedback in the starburst galaxy M82 and the degree of mass-loading of the hot gas piston driving its superwind by comparing a large suite of 1 and 2-dimensional hydrodynamical models to a set of observational constraints derived from hard X-ray observations of the starburst region (the fluxes of the He-alpha and Ly-alpha-like lines of S, Ar, Ca and Fe, along with the total diffuse E=2--8 keV X-ray luminosity). These are the first direct measurements of the feedback efficiency and mass-loading of supernova heated and enriched plasma in a starburst galaxy. All the models that satisfy the existing observational constraints have medium to high thermalization efficiencies (30% <= epsilon <= 100$%) and the volume-filling wind fluid that flows out of the starburst region is only mildly centrally mass loaded (1.0 <= beta <= 2.8). These results imply a temperature of the plasma within the starburst region in the range 30--80 million Kelvin, a mass flow rate of the wind fluid out of the starburst region of Mdot_tot ~ 1.4--3.6 Msol/yr and a terminal velocity of the wind in the range v_infinity = 1410--2240 km/s. This velocity is considerably larger than the escape velocity from M82 (v_esc <~ 460 km/s) and the velocity of the H-alpha emitting clumps and filaments within M82's wind (v_H-alpha ~ 600 km/s). Drawing on these results we provide a prescription for implementing starburst-driven superwinds in cosmological models of galaxy formation and evolution. (Abridged)