MHD simulations of dense core collision

TL;DR

This study uses 3D magnetohydrodynamic simulations to explore how magnetic fields influence dense core collisions and subsequent star formation, revealing dependencies on magnetic strength, collision offset, and angle.

Contribution

It provides new insights into the role of magnetic fields in core collisions and star formation, using detailed MHD simulations with varying parameters.

Findings

Higher magnetic fields reduce accretion rates.

Collision angle affects magnetic influence on star formation.

Off-center collisions with high angular momentum show complex gas dynamics.

Abstract

We investigated the effect of magnetic fields on the collision process between dense molecular cores. We performed three-dimensional magnetohydrodynamic simulations of collisions between two self-gravitating cores using the Enzo adaptive mesh refinement code. The core was modeled as a stable isothermal Bonnor-Ebert (BE) sphere immersed in uniform magnetic fields. Collisions were characterized by the offset parameter $b$, Mach number of the initial core $\mathcal{M}$, magnetic field strength $B_{0}$, and angle $\theta$ between the initial magnetic field and collision axis. For head-on ($b = 0$) collisions, one protostar was formed in the compressed layer. The higher the magnetic field strength, the lower the accretion rate. For models with $b = 0$ and $\theta = 90^{\circ}$, the accretion rate was more dependent on the initial magnetic field strength compared with $b = 0$ and $\theta = 0^{\circ}$ models. For off-center ($b = 1$) collisions, the higher specific angular momentum increased; therefore, the gas motion was complicated. In models with $b = 1$ and $\mathcal{M} = 1$, the number of protostars and gas motion highly depended on $B_{0}$ and $\theta$. For models with $b = 1$ and $\mathcal{M} = 3$, no significant shock-compressed layer was formed and star formation was not triggered.