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Title:
An explanation for the unusual IMF in Taurus
Authors:
Goodwin, S. P.; Whitworth, A. P.; Ward-Thompson, D.
Affiliation:
AA(Department of Physics and Astronomy, Cardiff University, PO Box 913, 5 The Parade, Cardiff CF24 3YB, UK), AB(Department of Physics and Astronomy, Cardiff University, PO Box 913, 5 The Parade, Cardiff CF24 3YB, UK), AC(Department of Physics and Astronomy, Cardiff University, PO Box 913, 5 The Parade, Cardiff CF24 3YB, UK)
Publication:
Astronomy and Astrophysics, v.419, p.543-547 (2004) (A&A Homepage)
Publication Date:
05/2004
Origin:
A&A
Astronomy Keywords:
stars: formation, ISM: clouds, ISM: structure, methods: numerical
DOI:
10.1051/0004-6361:20035802
Bibliographic Code:
2004A&A...419..543G

Abstract

In comparison with other well studied star formation regions, Taurus is unusual in several respects. (i) Its stellar initial mass function (IMF) peaks at relatively high mass (˜ 0.8 M), but contains very few stars much more massive than 1 M, and is relatively deficient in brown dwarfs. (ii) It has a higher binary fraction, particularly at large separations. (iii) Its core mass function is strongly peaked at a few M, and the cores have extended envelopes and relatively low levels of turbulence. We present here the results of an ensemble of hydrodynamic simulations which suggest that the unusual stellar IMF in Taurus is a direct consequence of the unusual properties of the cores there. By following the collapse and fragmentation of cores having properties typical of Taurus, we find that roughly 50% of the objects formed in a core, predominantly the low-mass ones, are ejected from the core to form a population of low-mass stars and brown dwarfs with a flat mass function. The remaining objects form multiple systems within the core, accreting until their masses approach 1 M; this produces a population of intermediate-mass stars whose mass function peaks at ˜ 0.8 M. Together these two populations reproduce the IMF in Taurus very well. This demonstrates, for the first time, a direct causal link between the core mass function and the stellar IMF in a star formation region.
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