Transport-driven super-Jeans fragmentation in dynamical star-forming regions

Abstract

The Jeans criterion is one cornerstone in our understanding of gravitational fragmentation. A critical limitation of the Jeans criterion is that the background density is assumed to be a constant, which is often not true in dynamic conditions such as star-forming regions. For example, during the formation phase of the high-density gas filaments in a molecular cloud, a density increase rate implies a mass accumulation time of t acc= / = - (∇ · ( v))-1. The system is non-stationary when the mass accumulation time becomes comparable to the free-fall time t ff = 1 / G . We study fragmentation in non-stationary settings, and find that accretion can significantly increase in the characteristic mass of gravitational fragmentation ( λ Jeans,\; aac= λ Jeans (1 + t ff / t acc)1/3, m Jeans,\, acc = m Jeans (1 + t ff / t acc)). In massive star-forming regions, this mechanism of transport-driven super-jeans fragmentation can contribute to the formation of massive stars by causing order-of-magnitude increases in the mass of the fragments.