Filamentary Star Formation: Observing the Evolution toward Flattened Envelopes

TL;DR

This paper proposes an observational scenario for filamentary star formation, suggesting small-scale filaments exist within starless cores and can be detected with advanced telescopes like ALMA, supporting a non-spherical star formation model.

Contribution

The study models the detectability of small-scale filamentary structures in star-forming regions using synthetic observations, highlighting the capabilities of ALMA and specific CARMA configurations.

Findings

CARMA D-array at 3mm cannot detect small filaments

CARMA D+E array at 3mm and E array at 1mm can detect filaments

ALMA can detect and resolve filamentary substructures in detail

Abstract

Filamentary structures are ubiquitous from large-scale molecular clouds (few parsecs) to small-scale circumstellar envelopes around Class 0 sources (~1000 AU to ~0.1 pc). In particular, recent observations with the Herschel Space Observatory emphasize the importance of large-scale filaments (few parsecs) and star formation. The small-scale flattened envelopes around Class 0 sources are reminiscent of the large-scale filaments. We propose an observationally derived scenario for filamentary star formation that describes the evolution of filaments as part of the process for formation of cores and circumstellar envelopes. If such a scenario is correct, small-scale filamentary structures (0.1 pc in length) with higher densities embedded in starless cores should exist, although to date almost all the interferometers have failed to observe such structures. We perform synthetic observations of filaments at the prestellar stage by modeling the known Class 0 flattened envelope in L1157 using both the Combined Array for Research in Millimeter-wave Astronomy (CARMA) and the Atacama Large Millimeter/Submillimeter Array (ALMA). We show that with reasonable estimates for the column density through the flattened envelope, the CARMA D-array at 3mm wavelengths is not able to detect such filamentary structure, so previous studies would not have detected them. However, the substructures may be detected with CARMA D+E array at 3 mm and CARMA E array at 1 mm as a result of more appropriate resolution and sensitivity. ALMA is also capable of detecting the substructures and showing the structures in detail compared to the CARMA results with its unprecedented sensitivity. Such detection will confirm the new proposed paradigm of non-spherical star formation.