Investigating the Gamma-Ray Emission from Explosive Dispersal Outflows with Fermi-LAT

Abstract

We present the first systematic study of explosive dispersal outflows (EDOs) as potential sources of high-energy emission in the Milky Way. EDOs are energetic outflows produced during dynamical interactions in young, massive star-forming regions, and their physical conditions make them promising environments for cosmic-ray acceleration. Using 16 years of 0.2--500 GeV Fermi-LAT observations, we study the gamma-ray properties of seven EDOs. Three EDOs, DR21, G34.26+0.15, and G5.89-0.39 show spatially coincident GeV emission, while the remaining systems yield non-detections. Among the sample, DR21 stands out as the brightest candidate, with a detection significance ≥ 40σ. Its spectrum is well described by a power law with an exponential cutoff, and the integrated luminosity in the 0.1--500 GeV band is Lγ 2×1035\ erg\ s-1. When compared with the outflow's estimated kinetic energy, the inferred cosmic-ray acceleration efficiency is ≤ 15\%, consistent with values for shocks in dense molecular environments. The energetics and morphology support an association between the DR21 molecular outflow and the observed gamma rays. Our results demonstrate that EDOs span a wide range of gamma-ray luminosities and efficiencies, suggesting they may contribute to the Galactic cosmic ray budget. This motivates searches for additional EDOs and improved multiwavelength characterization of their environments.