University of Illinois Urbana-Champaign

The electronic spectrum of para-ethynylbenzyl radical

Flores, Jonathan

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https://hdl.handle.net/2142/107584

Description

Title
The electronic spectrum of para-ethynylbenzyl radical
Author(s)
Flores, Jonathan
Contributor(s)
  • Reilly, Neil J.
  • Hewett, Daniel M.
  • Ross, Sederra D.
Issue Date
2020-06-23
Keyword(s)
Radicals
Abstract
Indenyl and phenylpropargyl are the most stable isomers of C$_9$H$_7$ and have emerged as ubiquitous products in flames and hydrocarbon discharges. Along with \textit{ortho}-ethynylbenzyl, they are the only C$_9$H$_7$ isomers to have been spectroscopically studied in detail, but there presumably exists a wide variety of other resonance-stabilized C$_9$H$_7$ radicals that have not yet been detected. We report the observation of \textit{para}-ethynylbenzyl radical, first found in a discharge of \textit{para}-vinyltoluene during an unsuccessful search for \textit{p}-vinylbenzyl, and subsequently observed with high signal-to-noise ratio when \textit{p}-ethynyltoluene was used as the precursor. Identification of the radical is secured by comparison of the observed (7.17\,eV) and calculated (7.08-7.25\,eV) adiabatic ionization energy, and a convincing assignment of the electronic spectrum can be made from calculated excited state frequencies. The molecule adopts $C$$_{2v}$ symmetry in its ground and first excited states. In almost every case where a single, strong $a_1$ fundamental is predicted in excitation, there exist two or more bright states in the spectrum. We attribute this to Fermi-resonance, a consequence of pervasive near-degeneracies of overtones of non-totally symmetric modes with Franck-Condon-active $a_1$ modes. Some instances have been confirmed by dispersed fluorescence spectroscopy at the time of writing. In addition, in the same \textit{m/z}\,=\,115 R2C2PI spectrum, we find unmistakable evidence of 1-phenylpropargyl, as well as the previously undetected \textit{m}-ethynylbenzyl radical. Examination of the precursor by NMR proves that both radicals are present at levels that cannot be accounted for by sample impurities unless computed transition strengths are too small by several orders of magnitude, suggesting rearrangement of all three radicals \textit{via} an intermediate that remains unobserved.
Publisher
International Symposium on Molecular Spectroscopy
Type of Resource
Text
Language
eng
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http://hdl.handle.net/2142/107584
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Copyright 2020 is held by the Author(s)

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Abstracts & Presentations - 2020 International Symposium on Molecular Spectroscopy PRIMARY