TY - JOUR
T1 - The fragmentation of magnetized, massive star-forming cores with radiative feedback
AU - Myers, Andrew T.
AU - McKee, Christopher F.
AU - Cunningham, Andrew J.
AU - Klein, Richard I.
AU - Krumholz, Mark R.
PY - 2013/4/1
Y1 - 2013/4/1
N2 - We present a set of three-dimensional, radiation-magnetohydrodynamic calculations of the gravitational collapse of massive (300 M⊙), star-forming molecular cloud cores. We show that the combined effects of magnetic fields and radiative feedback strongly suppress core fragmentation, leading to the production of single-star systems rather than small clusters. We find that the two processes are efficient at suppressing fragmentation in different regimes, with the feedback most effective in the dense, central region and the magnetic field most effective in more diffuse, outer regions. Thus, the combination of the two is much more effective at suppressing fragmentation than either one considered in isolation. Our work suggests that typical massive cores, which have mass-to-flux ratios of about 2 relative to critical, likely form a single-star system, but that cores with weaker fields may form a small star cluster. This result helps us understand why the observed relationship between the core mass function and the stellar initial mass function holds even for ∼100 M⊙ cores with many thermal Jeans masses of material. We also demonstrate that a ∼40 AU Keplerian disk is able to form in our simulations, despite the braking effect caused by the strong magnetic field.
AB - We present a set of three-dimensional, radiation-magnetohydrodynamic calculations of the gravitational collapse of massive (300 M⊙), star-forming molecular cloud cores. We show that the combined effects of magnetic fields and radiative feedback strongly suppress core fragmentation, leading to the production of single-star systems rather than small clusters. We find that the two processes are efficient at suppressing fragmentation in different regimes, with the feedback most effective in the dense, central region and the magnetic field most effective in more diffuse, outer regions. Thus, the combination of the two is much more effective at suppressing fragmentation than either one considered in isolation. Our work suggests that typical massive cores, which have mass-to-flux ratios of about 2 relative to critical, likely form a single-star system, but that cores with weaker fields may form a small star cluster. This result helps us understand why the observed relationship between the core mass function and the stellar initial mass function holds even for ∼100 M⊙ cores with many thermal Jeans masses of material. We also demonstrate that a ∼40 AU Keplerian disk is able to form in our simulations, despite the braking effect caused by the strong magnetic field.
KW - ISM: clouds
KW - magnetohydrodynamics (MHD)
KW - radiative transfer
KW - stars: formation
KW - stars: luminosity function, mass function
KW - turbulence
UR - http://www.scopus.com/inward/record.url?scp=84875436458&partnerID=8YFLogxK
U2 - 10.1088/0004-637X/766/2/97
DO - 10.1088/0004-637X/766/2/97
M3 - Article
SN - 0004-637X
VL - 766
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 2
M1 - 97
ER -