Freeze-out of the gas phase elements onto cold grains in dense interstellar
and circumstellar media builds up ice mantles consisting of molecules that are
mostly formed in situ (H2O, NH3, CO2, CO, CH3OH, and more). This review
summarizes the detected infrared spectroscopic ice features and compares the
abundances across Galactic, extragalactic, and solar system environments. A
tremendous amount of information is contained in the ice band profiles.
Laboratory experiments play a critical role in the analysis of the
observations. Strong evidence is found for distinct ice formation stages,
separated by CO freeze out at high densities. The ice bands have proven to be
excellent probes of the thermal history of their environment. The evidence for
the long-held idea that processing of ices by energetic photons and cosmic rays
produces complex molecules is weak. Recent state of the art observations show
promise for much progress in this area with planned infrared facilities.Comment: To appear in Annual Review of Astronomy and Astrophysics, volume 53,
2015. Updated 08/May/2015: corrected numbers in elemental budget section,
updated references and typo
To study the physical and chemical evolution of ices in solar-mass systems, a spectral survey is conducted of a sample of 41 low-luminosity YSOs (L $ 0:1Y10 L ) using 3Y38 m Spitzer and ground-based spectra. The sample is complemented with previously published Spitzer spectra of background stars and with ISO spectra of well-studied massive YSOs (L $ 10 5 L ). The long-known 6.0 and 6.85 m bands are detected toward all sources, with the Class 0Y type YSOs showing the deepest bands ever observed. The 6.0 m band is often deeper than expected from the bending mode of pure solid H 2 O. The additional 5Y7 m absorption consists of five independent components, which, by comparison to laboratory studies, must be from at least eight different carriers. Much of this absorption is due to simple species likely formed by grain surface chemistry, at abundances of 1%Y30% for CH 3 OH, 3%Y8% for NH 3 , 1%Y5% for HCOOH, $6% for H 2 CO, and $0.3% for HCOO À relative to solid H 2 O. The 6.85 m band has one or two carriers, of which one may be less volatile than H 2 O. Its carrier(s) formed early in the molecular cloud evolution and do not survive in the diffuse ISM. If an NH þ 4 -containing salt is the carrier, its abundance relative to solid H 2 O is $7%, demonstrating the efficiency of low-temperature acid-base chemistry or cosmic-rayYinduced reactions. Possible origins are discussed for enigmatic, very broad absorption between 5 and 8 m. Finally, the same ices are observed toward massive and low-mass YSOs, indicating that processing by internal UV radiation fields is a minor factor in their early chemical evolution.
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