TY - JOUR
T1 - Formation and desorption of sulphur chains (H2Sxand Sx) in cometary ice
T2 - effects of ice composition and temperature
AU - Carrascosa, H.
AU - Muñoz Caro, G. M.
AU - Martín-DomCrossed D sign©nech, R.
AU - Cazaux, S.
AU - Chen, Y. J.
AU - Fuente, A.
PY - 2024
Y1 - 2024
N2 - The reservoir of sulphur accounting for sulphur depletion in the gas of dense clouds and circumstellar regions is still unclear. One possibility is the formation of sulphur chains, which would be difficult to detect by spectroscopic techniques. This work explores the formation of sulphur chains experimentally, both in pure HS ice samples and in HO:HS ice mixtures. An ultrahigh vacuum chamber, ISAC, eqquipped with FTIR and QMS, was used for the experiments. Our results show that the formation of HS species is efficient, not only in pure HS ice samples, but also in water-rich ice samples. Large sulphur chains are formed more efficiently at low temperatures (10 K), while high temperatures (50 K) favour the formation of short sulphur chains. Mass spectra of HS, x = 2-6, species are presented for the first time. Their analysis suggests that HS species are favoured in comparison with S chains. Nevertheless, the detection of several S fragments at high temperatures in HS:HO ice mixtures suggests the presence of S in the irradiated ice samples, which could sublimate from 260 K. ROSINA instrument data from the cometary Rosetta mission detected mass-to-charge ratios 96 and 128. Comparing these detections with our experiments, we propose two alternatives: (1) HS and HS to be responsible of those S and S cations, respectively, or (2) S species, sublimating and being fragmented in the mass spectrometer. If S is the parent molecule, then S and S cations could be also detected in future missions by broadening the mass spectrometer range.
AB - The reservoir of sulphur accounting for sulphur depletion in the gas of dense clouds and circumstellar regions is still unclear. One possibility is the formation of sulphur chains, which would be difficult to detect by spectroscopic techniques. This work explores the formation of sulphur chains experimentally, both in pure HS ice samples and in HO:HS ice mixtures. An ultrahigh vacuum chamber, ISAC, eqquipped with FTIR and QMS, was used for the experiments. Our results show that the formation of HS species is efficient, not only in pure HS ice samples, but also in water-rich ice samples. Large sulphur chains are formed more efficiently at low temperatures (10 K), while high temperatures (50 K) favour the formation of short sulphur chains. Mass spectra of HS, x = 2-6, species are presented for the first time. Their analysis suggests that HS species are favoured in comparison with S chains. Nevertheless, the detection of several S fragments at high temperatures in HS:HO ice mixtures suggests the presence of S in the irradiated ice samples, which could sublimate from 260 K. ROSINA instrument data from the cometary Rosetta mission detected mass-to-charge ratios 96 and 128. Comparing these detections with our experiments, we propose two alternatives: (1) HS and HS to be responsible of those S and S cations, respectively, or (2) S species, sublimating and being fragmented in the mass spectrometer. If S is the parent molecule, then S and S cations could be also detected in future missions by broadening the mass spectrometer range.
KW - astrochemistry
KW - ISM: molecules
KW - methods: laboratory: molecular
KW - techniques: spectroscopic
KW - ultraviolet: ISM
UR - http://www.scopus.com/inward/record.url?scp=85201771541&partnerID=8YFLogxK
U2 - 10.1093/mnras/stae1768
DO - 10.1093/mnras/stae1768
M3 - Article
AN - SCOPUS:85201771541
SN - 0035-8711
VL - 533
SP - 967
EP - 978
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 1
ER -