On the interaction of a Bonnor-Ebert sphere with a stellar wind

TL;DR

This paper investigates how stellar winds can trigger gravitational collapse in Bonnor-Ebert spheres, deriving a new stability criterion and confirming it through simulations, which advances understanding of low-mass star formation mechanisms.

Contribution

It introduces a new analytical stability criterion for Bonnor-Ebert spheres compressed by stellar winds and validates it with numerical simulations, enhancing models of triggered star formation.

Findings

Stellar winds can trigger collapse in cores with specific nondimensional radii.

Collapse triggering efficiency decreases for smaller initial core sizes.

Winds can destabilize cores down to 0.5 solar masses under certain conditions.

Abstract

The structure of protostellar cores can often be approximated by isothermal Bonnor-Ebert spheres (BES) which are stabilized by an external pressure. For the typical pressure of $10^4k_B\,\mathrm{K\,cm^{-3}}$ to $10^5k_B\,\mathrm{K\,cm^{-3}}$ found in molecular clouds, cores with masses below $1.5\,{\rm M_\odot}$ are stable against gravitational collapse. In this paper, we analyze the efficiency of triggering a gravitational collapse by a nearby stellar wind, which represents an interesting scenario for triggered low-mass star formation. We derive analytically a new stability criterion for a BES compressed by a stellar wind, which depends on its initial nondimensional radius $\xi_{max}$. If the stability limit is violated the wind triggers a core collapse. Otherwise, the core is destroyed by the wind. We estimate its validity range to $2.5<\xi_{max}<4.2$ and confirm this in simulations with the SPH Code GADGET-3. The efficiency to trigger a gravitational collapse strongly decreases for $\xi_{max}<2.5$ since in this case destruction and acceleration of the whole sphere begin to dominate. We were unable to trigger a collapse for $\xi_{max}<2$, which leads to the conclusion that a stellar wind can move the smallest unstable stellar mass to $0.5\,\mathrm{M_\odot}$ and destabilizing even smaller cores would require an external pressure larger than $10^5k_B\,\mathrm{K\,cm^{-3}}$. For $\xi_{max}>4.2$ the expected wind strength according to our criterion is small enough so that the compression is slower than the sound speed of the BES and sound waves can be triggered. In this case our criterion underestimates somewhat the onset of collapse and detailed numerical analyses are required.