Protostellar Outflows Shed Light on the Dominant Close Companion Star Formation Pathways

TL;DR

This study analyzes 51 protostellar systems to determine their formation pathways, finding evidence that disk fragmentation is the dominant process for forming close companion stars, based on outflow and disk alignment data.

Contribution

It provides observational evidence supporting disk fragmentation as the main formation mechanism for close protostellar companions.

Findings

Outflows are preferentially orthogonal to companion disks.

Disk fragmentation likely dominates close-companion star formation.

Analysis of 51 systems supports the alignment hypothesis.

Abstract

Understanding the formation pathway for close-companion protostars is central to unraveling the processes that govern stellar multiplicity and very early star formation. We analyze a large sample of 51 Class 0/I close-companion protostellar systems, of which 38 show detectable outflows, yielding 42 measured outflows used in our analysis. We use ALMA observations of 11 systems in Perseus and 40 systems in Orion. These companions formed either directly at these small scales ($\lesssim 500$ au separations) via disk fragmentation or at larger scales ($> 1000$ au separations) via turbulent fragmentation followed by inward migration. Because of differences in formation mechanism, the former is expected to have preferentially aligned disks and outflows, whereas the latter is expected to show no preferred alignment. The relative prevalence of these formation pathways remains uncertain, yet it is critical to forming a comprehensive picture of star formation. We examine the distribution of position angles of companion protostars relative to the position angles of their molecular outflows. The outflow, as traced by $^{12}$CO ($J=2\rightarrow1$), is a useful proxy for the angular momentum of the system, expected to be orthogonal to the binary orbital plane. We use a simple model to account for random sampling of inclination and orbital phase in each system, finding that the observations are consistent with a distribution in which the outflows are preferentially orthogonal to the companions. Based on this analysis, we suggest disk fragmentation is the dominant formation pathway for close-companion protostellar systems.