Ice chemistry in embedded young stellar objects in the Large Magellanic   Cloud

J.M. Oliveira (Keele University); J. Th. van Loon (Keele); C.-H. R.; Chen (U. Virginia); A. G. G. M. Tielens (Leiden); G. C. Sloan (Cornell); P.; M. Woods (U. Manchester); F. Kemper (U. Manchester); R. Indebetouw (U.; Virginia); K. D. Gordon (STScI); M. L. Boyer (STScI); B. Shiao (STScI); S.; Madden (CEA); A. K. Speck (U. Missouri); M. Meixner (STScI); M. Marengo; (Iowa)

arXiv:0911.0532·astro-ph.SR·November 20, 2014

Ice chemistry in embedded young stellar objects in the Large Magellanic Cloud

J.M. Oliveira (Keele University), J. Th. van Loon (Keele), C.-H. R., Chen (U. Virginia), A. G. G. M. Tielens (Leiden), G. C. Sloan (Cornell), P., M. Woods (U. Manchester), F. Kemper (U. Manchester), R. Indebetouw (U., Virginia), K. D. Gordon (STScI), M. L. Boyer (STScI)

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TL;DR

This study investigates ice chemistry in embedded young stellar objects in the Large Magellanic Cloud using infrared spectroscopy, revealing water and CO2 ice features and evidence of thermal processing, with implications for star formation environments.

Contribution

First detailed analysis of ice features in LMC YSOs, showing similarities and differences with Galactic sources and suggesting enhanced CO2 production.

Findings

01

Water ice detected in two sources.

02

Significant CO2 ice in water-rich and pure forms.

03

Evidence of thermal processing in ice profiles.

Abstract

We present spectroscopic observations of a sample of 15 embedded young stellar objects (YSOs) in the Large Magellanic Cloud (LMC). These observations were obtained with the Spitzer Infrared Spectrograph (IRS) as part of the SAGE-Spec Legacy program. We analyze the two prominent ice bands in the IRS spectral range: the bending mode of CO_2 ice at 15.2 micron and the ice band between 5 and 7 micron that includes contributions from the bending mode of water ice at 6 micron amongst other ice species. The 5-7 micron band is difficult to identify in our LMC sample due to the conspicuous presence of PAH emission superimposed onto the ice spectra. We identify water ice in the spectra of two sources; the spectrum of one of those sources also exhibits the 6.8 micron ice feature attributed to ammonium and methanol. We model the CO_2 band in detail, using the combination of laboratory ice profiles…

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