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Description
The molecular composition of interstellar ice mantles is defined by gas-grain processes in molecular clouds, with the main components being H_2_O, CO, and CO_2_. Methanol (CH_3_OH) ice is detected towards the denser pre-stellar cores and star-forming regions, where large amounts of CO molecules freeze out and get hydrogenated on top of the icy grains. The thermal heating from nearby protostars can further change the ice structure and composition. Despite the several observations of icy features carried out towards molecular clouds and along the line of site of protostars, it is not yet clear if interstellar ices are mixed or if they have a layered structure. We aim to examine the effect of mixed and layered ice growth in dust grain mantle analogues, with specific focus on the position and shape of methanol infrared bands, so dedicated future observations could shed light on the structure of interstellar ices in different environments. Mixed and layered ice samples were deposited on a cold substrate kept at a temperature of 10K using a closed-cycle cryostat placed in a vacuum chamber. The spectroscopic features were analysed by Fourier transform infrared spectroscopy. Different proportions of the most abundant four molecular species in ice mantles, namely H_2_O, CO, CO_2_, and CH_3_OH, were investigated, with a special attention placed on the analysis of the CH_3_OH bands. We measure changes in the position and shape of the CH and CO stretching bands of CH_3_OH depending on the mixed or layered nature of the ice sample. Spectroscopic features of methanol are also found to change due to heating. A layered ice structure best reproduces the CH_3_OH band position recently observed towards a pre-stellar core and in star-forming regions. Based on our experimental results, we conclude that observations of CH_3_OH ice features in space can provide information about the structure of interstellar ices, and we expect the James Webb Space Telescope to put stringent constraints on the layered or mixed nature of ices in different interstellar environments, from molecular clouds to pre-stellar cores to protostars and protoplanetary discs.
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