Astronomy and Astrophysics – Astronomy
Scientific paper
Aug 1999
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1999apj...520..744b&link_type=abstract
The Astrophysical Journal, Volume 520, Issue 2, pp. 744-750.
Astronomy and Astrophysics
Astronomy
24
Stars: Binaries: General, Hydrodynamics, Ism: Clouds, Ism: Kinematics And Dynamics, Magnetohydrodynamics: Mhd, Stars: Formation
Scientific paper
Fragmentation during gravitational collapse has been reasonably successful at explaining the formation of binary and multiple stars, yet nearly all fragmentation calculations have ignored the effects of magnetic fields. The previous paper in this series attempted to remedy this oversight by including magnetic field effects in fully three-dimensional models of cloud collapse. These models allowed for magnetic field loss by ambipolar diffusion and showed that fragmentation is likely to occur during the resulting collapse of initially prolate, rapidly rotating, magnetically supported cloud cores. The main effect of the magnetic field was simply to delay the onset of the collapse phase. These calculations have now been extended to include the collapse of slowly rotating, magnetic clouds, including clouds that rotate so slowly that binary fragmentation does not occur. The new models show that a cloud initially in either solid-body or differential rotation can fragment into a binary protostar, provided that its ratio of rotational to gravitational energy (beta_i) exceeds about 0.01. Because the clouds with beta_i<0.01 fragment in the absence of magnetic fields, evidently magnetic fields can stifle fragmentation as well as delay collapse. The numerical models satisfy the Jeans conditions for physically realistic fragmentation, and a relatively high spatial resolution calculation indicates convergence to the binary fragmentation solution for rapidly rotating clouds. Because the critical value of beta_i for fragmentation falls close to the median of the observed distribution of rotational energies for dense molecular cloud cores, the results imply that roughly half of all cloud cores should form binary stars, a prediction that is consistent with the observed frequency of binary stars.
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