Unravelling the structure of magnetised molecular clouds with SILCC-Zoom: sheets, filaments and fragmentation

TL;DR

This study uses advanced simulations to explore how magnetic fields influence the formation, structure, and fragmentation of molecular clouds, revealing their role in shaping sheets, filaments, and dense regions in galactic environments.

Contribution

It provides the first detailed analysis of magnetic effects on cloud morphology and fragmentation using high-resolution, self-consistent simulations including magnetic fields, turbulence, and chemistry.

Findings

Magnetised clouds have more diffuse envelopes.

Most clouds are sheet-like with embedded filaments.

Magnetic fields delay cloud evolution and fragmentation by about 1 Myr.

Abstract

To what extent magnetic fields affect how molecular clouds (MCs) fragment and create dense structures is an open question. We present a numerical study of cloud fragmentation using the SILCC-Zoom simulations. These simulations follow the self-consistent formation of MCs in a few hundred parsec sized region of a stratified galactic disc; and include magnetic fields, self-gravity, supernova-driven turbulence, as well as a non-equilibrium chemical network. To discern the role of magnetic fields in the evolution of MCs, we study seven simulated clouds, five with magnetic fields, and two without, with a maximum resolution of 0.1 parsec. Using a dendrogram we identify hierarchical structures which form within the clouds. Overall, the magnetised clouds have more mass in a diffuse envelope with a number density between 1-100 cm$^{-3}$. We find that six out of seven clouds are sheet-like on the largest scales, as also found in recent observations, and with filamentary structures embedded within, consistent with the bubble-driven MC formation mechanism. Hydrodynamic simulations tend to produce more sheet-like structures also on smaller scales, while the presence of magnetic fields promotes filament formation. Analysing cloud energetics, we find that magnetic fields are dynamically important for less dense, mostly but not exclusively atomic structures (typically up to $\sim 100 - 1000$~cm$^{-3}$), while the denser, potentially star-forming structures are energetically dominated by self-gravity and turbulence. In addition, we compute the magnetic surface term and demonstrate that it is generally confining, and some atomic structures are even magnetically held together. In general, magnetic fields delay the cloud evolution and fragmentation by $\sim$ 1 Myr.