2012
DOI: 10.1051/0004-6361/201219628
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The impact of magnetic fields on the IMF in star-forming clouds near a supermassive black hole

Abstract: Star formation in the centers of galaxies is thought to yield massive stars with a possibly top-heavy stellar mass distribution. It is likely that magnetic fields play a crucial role in the distribution of stellar masses inside star-forming molecular clouds. In this context, we explore the effects of magnetic fields, with a typical field strength of 38 μG, such as in RCW 38, and a field strength of 135 μG, similar to NGC 2024 and the infrared dark cloud G28.34+0.06, on the initial mass function (IMF) near (≤10… Show more

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Cited by 7 publications
(6 citation statements)
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“…The authors attributed this difference to the suppression of intermediate mass stars from converging flows; magnetic support inhibited isolated collapse and instead stars formed predominantly within magnetized filaments, which tended to produce smaller mass stars. An anti-correlation between characteristic stellar mass and magnetic field strength was also demonstrated in simulations of star formation in the galactic center (Hocuk et al, 2012). In principle, a nonideal MHD treatment would allow the field to diffuse from magnetically subcritical regions, however, few simulations have included such effects and the impact on the shape of the IMF is unclear.…”
Section: Magnetic Field Strengthmentioning
confidence: 84%
“…The authors attributed this difference to the suppression of intermediate mass stars from converging flows; magnetic support inhibited isolated collapse and instead stars formed predominantly within magnetized filaments, which tended to produce smaller mass stars. An anti-correlation between characteristic stellar mass and magnetic field strength was also demonstrated in simulations of star formation in the galactic center (Hocuk et al, 2012). In principle, a nonideal MHD treatment would allow the field to diffuse from magnetically subcritical regions, however, few simulations have included such effects and the impact on the shape of the IMF is unclear.…”
Section: Magnetic Field Strengthmentioning
confidence: 84%
“…The former eject mass directly, while the latter lower accretion rates and inhibit the formation of massive collapsing regions Hocuk et al 2012). 1 The difficulty of teasing out the physics that is responsible for setting the IMF is partly driven by the fact that most simulations to date do not include all the possibly-important effects.…”
Section: Introductionmentioning
confidence: 99%
“…On top of all these processes, the characteristic mass scale can be shifted lower by both protostellar outflows (Hansen et al 2012;Krumholz, Klein & McKee 2012) and strong magnetic fields. The former eject mass directly, while the latter lower accretion rates and inhibit the formation of massive collapsing regions (Li et al 2010;Hocuk et al 2012). 1 The difficulty of teasing out the physics that is responsible for setting the IMF is partly driven by the fact that most simulations to date do not include all the possibly-important effects.…”
Section: Introductionmentioning
confidence: 99%
“…Indeed, enhanced accretion has been observed in numerical simulations in the presence of highly supersonic turbulence (Hobbs et al 2011), and more realistic approaches aim to self-consistently inject turbulent energy via supernova-explosions (Wada et al 2009). Other attempts have focused on the impact of black hole feedback on nearby starforming clouds (Hocuk & Spaans 2011), including the potential effects of magnetic fields (Hocuk et al 2012).…”
Section: Introductionmentioning
confidence: 99%