Understanding the TeV $\gamma$-ray emission surrounding the young massive star cluster Westerlund 1

TL;DR

This study interprets TeV gamma-ray observations around Westerlund 1, suggesting a leptonic origin for the emission and exploring particle acceleration mechanisms within the star cluster's superbubble.

Contribution

It provides a detailed model of gamma-ray emission considering both leptonic and hadronic processes, highlighting the leptonic origin as more plausible for Westerlund 1.

Findings

Leptonic emission explains the gamma-ray spectrum and morphology.

Hadronic models face confinement and energy requirement issues.

Magnetic fields and Klein-Nishina effects are crucial in spectral evolution.

Abstract

Context: Young massive star clusters (YMCs) have come increasingly into the focus of discussions on the origin of galactic cosmic rays (CRs). The proposition of CR acceleration inside superbubbles (SBs) blown by the strong winds of these clusters avoids issues faced by the standard paradigm of acceleration at supernova remnant shocks. Aims: We provide an interpretation of the latest TeV $\gamma$-ray observations of the region around the YMC Westerlund 1 taken with the High Energy Stereoscopic System (H.E.S.S.) in terms of diffusive shock acceleration at the cluster wind termination shock, taking into account the spectrum and morphology of the emission. As Westerlund 1 is a prototypical example of a YMC, such a study is relevant to the general question about the role of YMCs for the Galactic CR population. Methods: We generate model $\gamma$-ray spectra, characterise particle propagation inside the SB based on the advection, diffusion, and cooling timescales, and constrain key parameters of the system. We consider hadronic emission from proton-proton interaction and subsequent pion decay and leptonic emission from inverse Compton scattering on all relevant photon fields, including the CMB, diffuse and dust-scattered starlight, and the photon field of Westerlund 1 itself. The effect of the magnetic field on cooling and propagation is discussed. Klein-Nishina effects are found to be important in determining the spectral evolution of the electron population. Results: A leptonic origin of the bulk of the observed $\gamma$-rays is preferable. The model is energetically plausible, consistent with the presence of a strong shock, and allows for the observed energy-independent morphology. The hadronic model faces two main issues: confinement of particles to the emission region and an unrealistic energy requirement.