The Mass Distributions of Starless and Protostellar Cores in Gould Belt Clouds

TL;DR

This study develops a new method to classify dense cores in molecular clouds as starless or protostellar using combined submillimeter and infrared data, and analyzes their mass distributions across five clouds.

Contribution

It introduces a novel approach to distinguish core types and constructs self-consistent core mass functions, revealing their relation to the stellar initial mass function and cloud properties.

Findings

Core mass functions have slopes similar to the Salpeter IMF at high masses.

A potential correlation exists between high-mass slope and core temperature.

No clear trend between core mass and visual extinction was observed.

Abstract

Using data from the SCUBA Legacy Catalogue (850 um) and Spitzer Space Telescope (3.6 - 70 um), we explore dense cores in the Ophiuchus, Taurus, Perseus, Serpens, and Orion molecular clouds. We develop a new method to discriminate submillimeter cores found by SCUBA as starless or protostellar, using point source photometry from Spitzer wide field surveys. First, we identify infrared sources with red colors associated with embedded young stellar objects (YSOs). Second, we compare the positions of these YSO-candidates to our submillimeter cores. With these identifications, we construct new, self-consistent starless and protostellar core mass functions (CMFs) for the five clouds. We find best fit slopes to the high-mass end of the CMFs of -1.26 +/- 0.20, -1.22 +/- 0.06, -0.95 +/- 0.20, and -1.67 +/- 0.72 for Ophiuchus, Taurus, Perseus, and Orion, respectively. Broadly, these slopes are each consistent with the -1.35 power-law slope of the Salpeter IMF at higher masses, but suggest some differences. We examine a variety of trends between these CMF shapes and their parent cloud properties, potentially finding a correlation between the high-mass slope and core temperature. We also find a trend between core mass and effective size, but we are very limited by sensitivity. We make similar comparisons between core mass and size with visual extinction (for A_V >= 3) and find no obvious trends. We also predict the numbers and mass distributions of cores that future surveys with SCUBA-2 may detect in each of these clouds.