%0 Generic %1 haugbolle2017stellar %A Haugbølle, Troels %A Padoan, Paolo %A Nordlund, Aake %D 2017 %K IMF MHD isothermal turbulence %T The stellar IMF from Isothermal MHD Turbulence %U http://arxiv.org/abs/1709.01078 %X We address the turbulent-fragmentation scenario for the origin of the stellar initial mass function (IMF), using a large set of numerical simulations of randomly driven supersonic MHD turbulence. While radiation and outflows from protostars are often invoked, the turbulent-fragmentation model successfully predicts the main features of the observed stellar IMF assuming an isothermal equation of state without any stellar feedback. As a test of the model, we focus on the case of a magnetized isothermal gas, neglecting stellar feedback, while pursuing a large dynamic range in both space and time scales in order to generate a large number of stars, covering the full spectrum of stellar masses from brown dwarfs to massive stars. Our simulations represent a generic 4 pc region within a typical Galactic molecular cloud (MC), with a mass of 3,000 Msun, an rms velocity ten times the isothermal sound speed and five times the average Alfven velocity, in agreement with MC observations. We achieve a maximum resolution of 50 AU and a maximum duration of star formation of 4.0 Myr, forming up to a thousand sink particles whose mass distribution closely match the observed stellar IMF. A large set of medium-size simulations is used to test the sink particle scheme, while larger simulations are used to test the numerical convergence of the IMF and the dependence of the IMF turnover on physical parameters predicted by the turbulent-fragmentation model. We find clear evidence of numerical convergence and strong support for the model predictions, including the initial time evolution of the IMF. We conclude that the physics of isothermal MHD turbulence is sufficient to explain the origin of the IMF.

@misc{haugbolle2017stellar, abstract = {We address the turbulent-fragmentation scenario for the origin of the stellar initial mass function (IMF), using a large set of numerical simulations of randomly driven supersonic MHD turbulence. While radiation and outflows from protostars are often invoked, the turbulent-fragmentation model successfully predicts the main features of the observed stellar IMF assuming an isothermal equation of state without any stellar feedback. As a test of the model, we focus on the case of a magnetized isothermal gas, neglecting stellar feedback, while pursuing a large dynamic range in both space and time scales in order to generate a large number of stars, covering the full spectrum of stellar masses from brown dwarfs to massive stars. Our simulations represent a generic 4 pc region within a typical Galactic molecular cloud (MC), with a mass of 3,000 Msun, an rms velocity ten times the isothermal sound speed and five times the average Alfven velocity, in agreement with MC observations. We achieve a maximum resolution of 50 AU and a maximum duration of star formation of 4.0 Myr, forming up to a thousand sink particles whose mass distribution closely match the observed stellar IMF. A large set of medium-size simulations is used to test the sink particle scheme, while larger simulations are used to test the numerical convergence of the IMF and the dependence of the IMF turnover on physical parameters predicted by the turbulent-fragmentation model. We find clear evidence of numerical convergence and strong support for the model predictions, including the initial time evolution of the IMF. We conclude that the physics of isothermal MHD turbulence is sufficient to explain the origin of the IMF.}, added-at = {2017-09-14T09:12:10.000+0200}, author = {Haugbølle, Troels and Padoan, Paolo and Nordlund, Aake}, biburl = {https://www.bibsonomy.org/bibtex/2533a8ebd4b6701a04fabbbeaaec8944f/miki}, description = {[1709.01078] The stellar IMF from Isothermal MHD Turbulence}, interhash = {717aae71d99188b33d536a37d17a87fa}, intrahash = {533a8ebd4b6701a04fabbbeaaec8944f}, keywords = {IMF MHD isothermal turbulence}, note = {cite arxiv:1709.01078Comment: 25 pages, 21 figures}, timestamp = {2017-09-14T09:12:10.000+0200}, title = {The stellar IMF from Isothermal MHD Turbulence}, url = {http://arxiv.org/abs/1709.01078}, year = 2017 }