The influence of magnetic fields in Cloud-Cloud Collisions

Abstract Cloud-cloud collisions are expected to trigger star formation by compressing gas into dense, gravitationally unstable regions. However, the role of magnetic fields in this process is unclear. We use SPH to model head-on collisions between two uniform density clouds, each with mass 500\, M_, initial radius 2 pc, and threaded by a uniform magnetic field parallel to the collision velocity. As in the non-magnetic case, the resulting shock-compressed layer fragments into a network of filaments. If the collision is sufficiently slow, the filaments are dragged into radial orientations by non-homologous gravitational contraction, resulting in a Hub-Filament morphology, which spawns a centrally concentrated monolithic cluster with a broad mass function shaped by competitive accretion and dynamical ejections. If the collision is faster, a Spiders-Web of intersecting filaments forms, and star-systems condense out in small sub-clusters, often at the filament intersections; due to their smaller mass reservoirs, and the lower probability of dynamical ejection, the mass function of star-systems formed in these sub-clusters is relatively narrow. Magnetic fields affect this dichotomy quantitatively by delaying collapse and fragmentation. As a result, the velocity threshold separating Hub-Filament and Spiders-Web morphologies is shifted upward in magnetised runs, thereby enlarging the parameter space in which Hub-Filament Systems form, and enhancing the likelihood of producing centrally concentrated clusters. Thus magnetic fields regulate both the morphology and timing of star formation in cloud-cloud collisions: they broaden filaments, delay the onset of star formation, and promote the formation of Hub-Filament Systems monolithic clusters and high-mass star-systems.