Radiation-induced transformations of isolated phosphine molecules at cryogenic temperatures: Spectroscopic and chemical aspects

The radiation-induced transformations of isolated phosphine molecules in a series of solid noble gas matrices occurring under the action of X-rays at 4.5 K were studied by FTIR spectroscopy. It was shown that decomposition was quite efficient (the corresponding radiation-chemical yields of PH3 degra...

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Bibliographic Details
Published in:Radiation physics and chemistry (Oxford, England : 1993) England : 1993), 2023-05, Vol.206, p.110786, Article 110786
Main Authors: Shiryaeva, Ekaterina S., Panfutov, Oleg D., Tyurin, Daniil A., Feldman, Vladimir I.
Format: Article
Language:English
Subjects:
FTIR-Spectroscopy
Matrix isolation
Phosphine
VUV photolysis
X-ray irradiation
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Summary:The radiation-induced transformations of isolated phosphine molecules in a series of solid noble gas matrices occurring under the action of X-rays at 4.5 K were studied by FTIR spectroscopy. It was shown that decomposition was quite efficient (the corresponding radiation-chemical yields of PH3 degradation were estimated as 5.8, 4.2, 3.5, and 2.0 molecules per 100 eV for neon, argon, krypton, and xenon, respectively). The radiolysis proceeds via two channels yielding PH2• and PH, respectively (the spectroscopic and kinetic data suggest that the latter species is partially trapped in the same cage with hydrogen molecules). Comparative studies using direct activation of isolated phosphine molecules in matrices at λ = 185 nm revealed similarity in the degradation pathways under radiolysis and VUV photolysis. Spectroscopic characteristics of the observed products and possible astrochemical implications of the results are discussed. •Degradation of matrix isolated PH3 under the action of X-ray and VUV radiation at 4.5 K was studied.•PH2 and PH species are efficiently produced in both cases.•PH originates from both single-step and two-step decomposition of PH3 molecules.•A complex structure of infrared absorption bands was attributed to matrix site splitting.
ISSN:0969-806X
1879-0895
DOI:10.1016/j.radphyschem.2023.110786