Resolution-dependent Subsonic Non-thermal Line Dispersion Revealed by ALMA

TL;DR

This study uses high-resolution ALMA observations to reveal that dense gas in Orion Molecular Cloud 2/3 is predominantly subsonic, and demonstrates that previously observed supersonic line widths are due to unresolved sub-structures and limited spatial resolution.

Contribution

The paper provides the first high-resolution analysis showing the transition from supersonic to subsonic turbulence at ~0.05 pc scales in a massive star-forming region, clarifying the nature of turbulence.

Findings

Most dense gas in OMC-2/3 is subsonic with line widths of 0.39 km/s.

Larger line widths from single-dish observations are due to unresolved sub-structures.

Non-thermal line dispersion transitions from supersonic to subsonic at ~0.05 pc scales.

Abstract

We report here Atacama Large Millimeter/submillimeter Array (ALMA) N$_2$H$^+$ (1-0) images of the Orion Molecular Cloud 2 and 3 (OMC-2/3) with high angular resolution (3'' or 1200 au) and high spatial dynamic range. Combining dataset from the ALMA main array, ALMA Compact Array (ACA), the Nobeyama 45m Telescope, and the JVLA (providing temperature measurement on matching scales), we find that most of the dense gas in OMC-2/3 is subsonic ($\rm \sigma_{NT}/c_{s}$ = 0.62) with a mean line width ($\Delta\upsilon$) of 0.39 km s$^{-1}$ FWHM. This is markedly different from the majority of previous observations of massive star-forming regions. In contrast, line widths from the Nobeyama Telescope are transonic at 0.69 km s$^{-1}$ ($\rm \sigma_{NT}/c_{s}$ = 1.08). We demonstrated that the larger line widths obtained by the single-dish telescope arose from unresolved sub-structures within their respective beams. The dispersions from larger scales $\sigma_{ls}$ (as traced by the Nobeyama Telescope) can be decomposed into three components $\rm \sigma_{ls}^2 = \sigma_{ss}^2+ \sigma_{bm}^2+ \sigma_{rd}^2$, where small-scale $\sigma_{ss}$ is the line dispersion of each ALMA beam, bulk motion $\sigma_{bm}$ is dispersion between peak velocity of each ALMA beam, and $\sigma_{rd}$ is the residual dispersion. Such decomposition, though purely empirical, appears to be robust throughout our data cubes. Apparent supersonic line widths, commonly found in massive molecular clouds, are thus likely due to the effect of poor spatial resolution. The observed non-thermal line dispersion (sometimes referred to as 'turbulence') transits from supersonic to subsonic at $\sim 0.05$ pc scales in OMC-2/3 region. Such transition could be commonly found with sufficient spatial (not just angular) resolution, even in regions with massive young clusters, such as Orion molecular clouds studied here.