Spectroscopic observations of ices around embedded young stellar objects in the Large Magellanic Cloud with AKARI

TL;DR

This study used AKARI infrared spectroscopy to analyze ices around young stellar objects in the LMC, revealing higher CO2 ice ratios compared to the Milky Way, likely due to environmental factors like UV radiation and dust temperature.

Contribution

First near-infrared spectroscopic survey of ices around YSOs in the LMC, showing environmental effects on ice compositions compared to Galactic counterparts.

Findings

The CO2/H2O ice ratio in LMC YSOs is higher than in the Milky Way.

No correlation between ice abundances and YSO luminosity or other characteristics.

High CO2 ice abundance likely due to UV radiation and dust temperature in the LMC.

Abstract

The aim of this study is to understand the chemical conditions of ices around embedded young stellar objects (YSOs) in the metal-poor Large Magellanic Cloud (LMC). We performed near-infrared (2.5-5 micron) spectroscopic observations toward 12 massive embedded YSOs and their candidates in the LMC using the Infrared Camera (IRC) onboard AKARI. We estimated the column densities of the H2O, CO2, and CO ices based on their 3.05, 4.27, and 4.67 micron absorption features, and we investigated the correlation between ice abundances and physical properties of YSOs.The ice absorption features of H2O, CO2, 13CO2, CO, CH3OH, and possibly XCN are detected in the spectra. In addition, hydrogen recombination lines and PAH emission bands are detected toward the majority of the targets. The derived typical CO2/H2O ice ratio of our samples (~0.36 +- 0.09) is greater than that of Galactic massive YSOs (~0.17 +- 0.03), while the CO/H2O ice ratio is comparable. It is shown that the CO2 ice abundance does not correlate with the observed characteristics of YSOs; the strength of hydrogen recombination line and the total luminosity. Likewise, clear no correlation is seen between the CO ice abundance and YSO characteristics, but it is suggested that the CO ice abundance of luminous samples is significantly lower than in other samples.The systematic difference in the CO2 ice abundance around the LMC's massive YSOs, which was suggested by previous studies, is confirmed with the new near-infrared data. We suggest that the strong ultraviolet radiation field and/or the high dust temperature in the LMC are responsible for the observed high abundance of the CO2 ice. It is suggested that the internal stellar radiation does not play an important role in the evolution of the CO2 ice around a massive YSO, while more volatile molecules like CO are susceptible to the effect of the stellar radiation.