Star Formation triggered by cloud-cloud collisions
Abstract
We present the results of SPH simulations in which two clouds, each having mass and radius , collide head-on at relative velocities of . There is a clear trend with increasing . At low , star formation starts later, and the shock-compressed layer breaks up into an array of predominantly radial filaments; stars condense out of these filaments and fall, together with residual gas, towards the centre of the layer, to form a single large- cluster, which then evolves by competitive accretion, producing one or two very massive protostars and a diaspora of ejected (mainly low-mass) protostars; the pattern of filaments is reminiscent of the hub and spokes systems identified recently by observers. At high , star formation occurs sooner and the shock-compressed layer breaks up into a network of filaments; the pattern of filaments here is more like a spider's web, with several small- clusters forming independently of one another, in cores at the intersections of filaments, and since each core only spawns a small number of protostars, there are fewer ejections of protostars. As the relative velocity is increased, the {\it mean} protostellar mass increases, but the {\it maximum} protostellar mass and the width of the mass function both decrease. We use a Minimal Spanning Tree to analyse the spatial distributions of protostars formed at different relative velocities.
Cite
@article{arxiv.1509.05287,
title = {Star Formation triggered by cloud-cloud collisions},
author = {S. K. Balfour and A. P. Whitworth and D. A. Hubber and S. E. Jaffa},
journal= {arXiv preprint arXiv:1509.05287},
year = {2015}
}
Comments
10 pages, 11 figures