The necessity of feedback physics in setting the peak of the initial mass function
Date
2016
Authors
Guszejnov, David
Krumholz, Mark
Hopkins, Philip F.
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Blackwell Publishing Ltd
Abstract
A popular theory of star formation is gravito-turbulent fragmentation, in which self-gravitating
structures are created by turbulence-driven density fluctuations. Simple theories of isothermal
fragmentation successfully reproduce the core mass function (CMF) which has a very similar
shape to the initialmass function (IMF) of stars. However, numerical simulations of isothermal
turbulent fragmentation thus far have not succeeded in identifying a fragment mass scale that is independent of the simulation resolution. Moreover, the fluid equations for magnetized, selfgravitating, isothermal turbulence are scale-free, and do not predict any characteristic mass. In this paper we show that, although an isothermal self-gravitating flow does produce a CMF with a mass scale imposed by the initial conditions, this scale changes as the parent cloud evolves. In addition, the cores that form undergo further fragmentation and after sufficient time forget about their initial conditions, yielding a scale-free pure power-law distribution dN/dM ∝ M−2 for the stellar IMF. We show that this problem can be alleviated by introducing additional physics that provides a termination scale for the cascade. Our candidate for such physics is a simple model for stellar radiation feedback. Radiative heating, powered by accretion on to forming stars, arrests the fragmentation cascade and imposes a characteristic mass scale that is nearly independent of the time-evolution or initial conditions in the star-forming cloud, and
that agrees well with the peak of the observed IMF. In contrast, models that introduce a stiff
equation of state for denser clouds but that do not explicitly include the effects of feedback do
not yield an invariant IMF.
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Monthly Notices of the Royal Astronomical Society
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Journal article
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Open Access
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