On the role of gravity, turbulence, and the magnetic field in angular momentum transfer within molecular clouds

TL;DR

This study investigates how gravity, turbulence, and magnetic fields influence angular momentum transfer and filament formation in molecular clouds through SPH simulations.

Contribution

It provides a comparative analysis of the effects of gravity, turbulence, and magnetic fields on angular momentum scaling and filamentary structures in molecular clouds.

Findings

Elongated clumps deviate from the j-R relation in non-magnetic runs.

Turbulence alone does not produce dense filaments, but clumps still match observed angular momentum.

Hydrodynamic torques dominate over magnetic and gravitational torques in magnitude.

Abstract

Observations of molecular structures on scales of $\sim 0.1-50$ pc show that the specific angular momentum ($j$) scales with radius ($R$) as $j\sim R^{3/2}$. We study the effects of turbulence, gravity, and the magnetic field in shaping this scaling, by measuring clump size and specific angular momentum in three SPH simulations of the formation of giant molecular clouds, progressively adding these three ingredients. In each simulation, we define ``full'' and ``reduced'' clump samples, the latter restricted to aspect ratios $A<3$. We find that, in the non-magnetic runs, elongated clumps deviate the most from the \jR\ relation, which is best reproduced by the reduced sample in the gravity+turbulence run. In the purely hydrodynamic case, no dense elongated structures form, suggesting that turbulence alone is insufficient to generate dense filaments, although clumps have $j$ magnitudes consistent with observations. In the gravity+turbulence+magnetic field run, most of the clumps are filamentary, yet the full sample appears to follow the observed \jR\ relation. This result, rather than being a real trend, could be the combination of the increase in $j$ by the filamentary geometry, and its reduction by turbulence inhibition by the magnetic field. Finally, we measure the gravitational, magnetic, pressure-gradient, and hydrodynamic torques (which involve turbulent viscosity) in our clump samples. We find that, in magnitude, the hydrodynamic torques tend to be larger than the rest. This result is consistent with our previous work, where we proposed that gravity drives cloud formation and contraction, while turbulence redistributes angular momentum through fluid-parcel exchanges.