Particle acceleration in the superwinds of starburst galaxies

Starbursts are galaxies undergoing massive episodes of star formation. The combined effect of stellar winds from hot stars and supernova explosions creates a high-temperature cavity in the nuclear region of these objects. The very hot gas expands adiabatically and escapes from the galaxy creating a superwind which sweeps matter from the galactic disk. The superwind region in the halo is filled with a multi-phase gas with hot, warm, cool, and relativistic components. The shocks associated with the superwind of starbursts and the turbulent gas region of the bubble inflated by them might accelerate cosmic rays up to high energies. In this work we calculate the cosmic ray production associated with the superwind using parameters that correspond to the nearby southern starburst galaxy NGC 253, which has been suggested as a potential accelerator of ultra-high energy cosmic rays. We evaluate the efficiency of both diffusive shock acceleration (DSA) and stochastic diffusive acceleration (SDA) in the superwind of NGC 253. We estimate the distribution of both hadrons and leptons and calculate the corresponding spectral energy distributions of photons. We find that the strong mass load of the superwind, recently determined through ALMA observations, strongly attenuates the efficiency of DSA in NGC 253, whereas SDA is constrained by the age of the starburst. We conclude that NGC 253 and similar starbursts can only accelerate iron nuclei beyond $\sim10^{18}$ eV under very special conditions. If the central region of the galaxy harbors a starved supermassive black hole of $\sim10^6$ $M_{\odot}$, as suggested by some recent observations, a contribution in the range $10^{18}-10^{19}$ eV can be present for accretion rates $\dot{m}\sim10^{-3}$ in Eddington units. Only if very strong magnetic field amplification occurs close to the superwind shock energies of the order of 100 EeV might be achieved.