The Magnetic Field versus Density relation in Star-Forming Molecular Clouds

Abstract: We study the magnetic field to density ($B-\rho$) relation in turbulent molecular clouds with dynamically important magnetic fields using nonideal three-dimensional magnetohydrodynamic simulations. Our simulations show that there is a distinguishable break density $\rho_{\rm T}$ between the relatively flat low density regime and a power-law regime at higher densities. We present an analytic theory for $\rho_{\rm T}$ based on the interplay of the magnetic field, turbulence, and gravity. The break density $\rho_{\rm T}$ scales with the strength of the initial Alfv\'en Mach number $\mathcal{M}{\rm A0}$ for sub-Alfv\'enic ( $\mathcal{M}{\rm A0}<1$) and trans-Alfv\'enic ($\mathcal{M}{\rm A0} \sim 1$) clouds. We fit the variation of $\rho{\rm T}$ for model clouds as a function of $\mathcal{M}{\rm A0}$, set by different values of initial sonic Mach number $\mathcal{M{\rm 0}}$ and the initial ratio of gas pressure to magnetic pressure $\beta_{\rm 0}$. This implies that $\rho_{\rm T}$, which denotes the transition in mass-to-flux ratio from the subcritical to supercritical regime, is set by the initial turbulent compression of the molecular cloud.