The Impact of Feedback During Massive Star Formation by Core Accretion

Kei E. I. Tanaka, Jonathan C. Tan, Yichen Zhang

Published 2016-10-27Version 1

We study the impact of feedback during the formation of massive stars that are accreting from massive gas cores using analytic method. MHD-driven disk winds are known to be the primary feedback mechanism for low-mass star formation. Radiative feedback processes are also expected to become significant for more massive protostars. We model feedback from disk winds, radiation pressure, photoevaporation and stellar winds, while following protostellar evolution in a series of models of collapsing massive cores. We find disk winds are the dominant feedback mechanism for massive star formation from cores in clump environments with surface densities Sigma>0.3g/cm2. >90% of total momentum is input by the disk wind, however radiation pressure also assists in widening the outflow cavity. Photoevaporation is of relatively minor importance due to dust attenuation of ionizing photons. Mass-loss and momentum feedback from stellar winds have very minor effects during the accretion stage. We find the SFE from the cores to be 0.4(Mc/100Msun)^{-0.115} for core masses Mc~10-1e3Msun and Sigma=1g/cm2. The decline of SFE with core mass is gradual and we do not find any evidence for a maximum stellar mass set by feedback processes up to stellar masses of 300Msun. We thus conclude the observed truncation of the high-mass end of the IMF is shaped mostly by the prestellar core mass function or internal stellar processes, rather than by feedback. To form massive stars with the observed maximum masses of 150-300Msun by core accretion, initial core masses need to be >500-1000Msun. We apply our feedback model to zero metallicity primordial star formation, showing that, in the absence of dust, photoevaporation staunches mass accretion at around 50Msun. Our model implies radiative feedback is most significant at metallicities 1e-2Zsun, since both radiation pressure and photoevaporation are effective in this regime.