Molecular Cloud Cores with High Deuterium Fraction: Nobeyama Single-Pointing Survey

TL;DR

This survey of 207 dense cores across various Galactic environments reveals chemical evolution indicators, deuterium fraction variations, and insights into initial star formation conditions, with most cores being chemically evolved and some close to star formation onset.

Contribution

First comprehensive molecular line survey of dense cores in diverse environments, highlighting chemical evolution and deuterium fraction as star formation indicators.

Findings

Most cores are chemically evolved with high detection rates of late-type molecules.

Deuterium fraction decreases with distance due to beam dilution effects.

Identified high D/H cores likely near star formation onset.

Abstract

We present the results of a single-pointing survey of 207 dense cores embedded in Planck Galactic Cold Clumps distributed in five different environments ($\lambda$ Orionis, Orion A, B, Galactic plane, and high latitudes) to identify dense cores on the verge of star formation for the study of the initial conditions of star formation. We observed these cores in eight molecular lines at 76-94 GHz using the Nobeyama 45-m telescope. We find that early-type molecules (e.g., CCS) have low detection rates and that late-type molecules (e.g., N$_2$H$^+$, c-C$_3$H$_2$) and deuterated molecules (e.g., N$_2$D$^+$, DNC) have high detection rates, suggesting that most of the cores are chemically evolved. The deuterium fraction (D/H) is found to decrease with increasing distance, indicating that it suffers from differential beam dilution between the D/H pair of lines for distant cores ($>$1 kpc). For $\lambda$ Orionis, Orion A, and B located at similar distances, D/H is not significantly different, suggesting that there is no systematic difference in the observed chemical properties among these three regions. We identify at least eight high D/H cores in the Orion region and two at high latitudes, which are most likely to be close to the onset of star formation. There is no clear evidence of the evolutionary change in turbulence during the starless phase, suggesting that the dissipation of turbulence is not a major mechanism for the beginning of star formation as judged from observations with a beam size of 0.04 pc.