SIMBAD references

We have begun a systematic numerical study of the nonlinear growth of nonaxisymmetric perturbations during the ambipolar diffusion-driven evolution of initially magnetically subcritical molecular clouds, with an eye on the formation of binaries, multiple stellar systems, and small clusters. In this initial study, we focus on the m=2 (or bar) mode, which is shown to be unstable during the dynamic collapse phase of cloud evolution after the central region has become magnetically supercritical. We find that despite the presence of a strong magnetic field, the bar can grow fast enough that for a modest initial perturbation (at the 5% level), a large aspect ratio is obtained during the isothermal phase of cloud collapse. The highly elongated bar is expected to fragment into small pieces during the subsequent adiabatic phase. Our calculations suggest that the strong magnetic fields observed in some star-forming clouds and envisioned in the standard picture of single star formation do not necessarily suppress bar growth and fragmentation; on the contrary, they may actually promote these processes by allowing the clouds to have more than one (thermal) Jeans mass to begin with, without collapsing promptly. Nonlinear growth of the bar mode in a direction perpendicular to the magnetic field coupled with flattening along field lines leads to the formation of supercritical cores that are triaxial in general. It removes a long-standing objection to the standard scenario of isolated star formation involving subcritical magnetic field and ambipolar diffusion based on the likely prolate shape inferred for dense cores. Continued growth of the bar mode in already elongated starless cores, such as L1544, may lead to future binary and multiple star formation.