Issue 10, 2019, Issue in Progress

VUV spectroscopy of an electron irradiated benzene : carbon dioxide interstellar ice analogue

Abstract

We present the first vacuum ultraviolet spectroscopic study of an interstellar ice analogue of a 1 : 100 benzene (C6H6) : carbon dioxide (CO2) mixture which has been energetically processed with 1 keV electrons. We have exploited the fact that benzene has a relatively high photoabsorption cross section in the vacuum ultraviolet region to study this dilute mixture of benzene. Before irradiation with 1 keV electrons, we observed that the benzene electronic transition bands in the C6H6 : CO2 mixture exhibits a blueshift in band position towards energies observed in the gas-phase compared with that of pure, amorphous benzene and we have attributed this to a matrix isolation effect. After irradiation, a lowering in intensity of both the carbon dioxide and benzene electronic transition bands was observed, as well as the formation of the small irradiation product, carbon monoxide. A residue was obtained at 200 K which showed characteristic features of the benzene electronic transition of 1E1u1A1g, but with additional structure suggesting the formation of a benzene derivative.

Graphical abstract: VUV spectroscopy of an electron irradiated benzene : carbon dioxide interstellar ice analogue

Article information

Article type
Paper
Submitted
18 Jan 2019
Accepted
03 Feb 2019
First published
13 Feb 2019
This article is Open Access
Creative Commons BY license

RSC Adv., 2019,9, 5453-5459

VUV spectroscopy of an electron irradiated benzene : carbon dioxide interstellar ice analogue

R. L. James, N. C. Jones, S. V. Hoffmann and A. Dawes, RSC Adv., 2019, 9, 5453 DOI: 10.1039/C9RA00462A

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