The c2d Spitzer spectroscopic survey of ices around low-mass young stellar objects II: CO2

TL;DR

This study uses Spitzer-IRS spectroscopy to analyze CO2 ice around 50 low-mass young stars, revealing complex ice compositions, formation processes, and thermal evolution in protostellar environments.

Contribution

It provides detailed decomposition of CO2 ice profiles and models the formation and thermal processing of CO2 and CO ices in low-mass star-forming regions.

Findings

Average CO2 abundance is higher than in quiescent clouds.

CO2 ice profiles require at least five components.

Thermal processing causes CO2 profile evolution, including band splitting.

Abstract

This paper presents Spitzer-IRS spectroscopy of the CO2 15.2 micron bending mode toward a sample of 50 embedded low-mass stars in nearby star-forming clouds, taken mostly from the ``Cores to Disks (c2d)'' Legacy program. The average abundance of solid CO2 relative to water in low-mass protostellar envelopes is 0.32 +/- 0.02, significantly higher than that found in quiescent molecular clouds and in massive star forming regions. It is found that a decomposition of all the observed CO2 bending mode profiles requires a minimum of five unique components. Roughly 2/3 of the CO2 ice is found in a water-rich environment, while most of the remaining 1/3 is found in a CO environment. Ground-based observations of solid CO toward a large subset of the c2d sample are used to further constrain the CO2:CO component and suggest a model in which low-density clouds form the CO2:H2O component and higher density clouds form the CO2:CO ice during and after the freeze-out of gas-phase CO. It is suggested that the subsequent evolution of the CO2 and CO profiles toward low-mass protostars, in particular the appearance of the splitting of the CO2 bending mode due to pure, crystalline CO2, is first caused by distillation of the CO2:CO component through evaporation of CO due to thermal processing to ~20-30 K in the inner regions of infalling envelopes. The formation of pure CO2 via segregation from the H2O rich mantle may contribute to the band splitting at higher levels of thermal processing (>50 K), but is harder to reconcile with the physical structure of protostellar envelopes around low-luminosity objects.