Chaotic star formation and the alignment of stellar rotation with disc and planetary orbital axes

TL;DR

This study explores how chaotic accretion and dynamical interactions in stellar clusters lead to misaligned stellar rotation axes and circumstellar discs, affecting planetary system orientations and jet directions.

Contribution

It demonstrates that dynamical encounters can cause significant misalignments between stellar and disc axes, influencing planetary system configurations and jet variability.

Findings

Misalignments occur mainly due to disc truncation by encounters.

Jet directions vary more in lighter, truncated discs.

Stellar internal velocity fields may be more complex than aligned models.

Abstract

We investigate the evolution of the relative angle between the stellar rotation axis and the circumstellar disc axis of a star that forms in a stellar cluster from the collapse of a turbulent molecular cloud. This is an inherently chaotic environment with variable accretion, both in terms of rate and the angular momentum of the material, and dynamical interactions between stars. We find that the final stellar rotation axis and disc spin axis can be strongly misaligned, but this occurs primarily when the disc is truncated by a dynamical encounter so that the final disc rotation axis depends simply on what fell in last. This may lead to planetary systems with orbits that are misaligned with the stellar rotation axis, but only if the final disc contains enough mass to form planets. We also investigate the time variability of the inner disc spin axis, which is likely to determine the direction of a protostellar jet. We find that the jet direction varies more strongly for lighter discs, such as those that have been truncated by dynamical interactions or have suffered a period of rapid accretion. Finally, we note that variability of the angular momentum of the material accreting by a star implies that the internal velocity field of such stars may be more complicated than that of aligned differential rotation.