SILCC-ZOOM: The early impact of ionizing radiation on forming molecular clouds

TL;DR

This study uses high-resolution radiation-hydrodynamic simulations to investigate how ionizing radiation from massive stars influences molecular cloud evolution and star formation efficiency, revealing significant cloud dispersal and low star formation rates.

Contribution

First detailed sub-parsec resolution simulations of molecular clouds incorporating self-consistent ionizing radiation effects from massive stars.

Findings

Star formation efficiency is reduced by a factor of ~4 due to radiation.

Radiation triggers star formation across the clouds.

Cloud dispersal time depends on substructure and gas shielding.

Abstract

As part of the SILCC-ZOOM project we present our first sub-parsec resolution radiation-hydrodynamic simulations of two molecular clouds self-consistently forming from a turbulent, multi-phase ISM. The clouds have similar initial masses of few 10$^4$ M$_{\odot}$, escape velocities of ~5 km s$^{-1}$, and a similar initial energy budget. We follow the formation of star clusters with a sink based model and the impact of radiation from individual massive stars with the tree-based radiation transfer module TreeRay. Photo-ionizing radiation is coupled to a chemical network to follow gas heating, cooling and molecule formation and dissociation. For the first 3 Myr of cloud evolution we find that the overall star formation effciency is considerably reduced by a factor of ~4 to global cloud values of < 10 % as the mass accretion of sinks that host massive stars is terminated after <1 Myr. Despite the low effciency, star formation is triggered across the clouds. Therefore, a much larger region of the cloud is affected by radiation and the clouds begin to disperse. The time scale on which the clouds are dispersed sensitively depends on the cloud substructure and in particular on the amount of gas at high visual extinction. The damage of radiation done to the highly shielded cloud (MC1) is delayed. We also show that the radiation input can sustain the thermal and kinetic energy of the clouds at a constant level. Our results strongly support the importance of ionizing radiation from massive stars for explaining the low observed star formation effciency of molecular clouds