The phosphorescence of benzene: Zeeman effect and microwave induced emission
- 1 November 1973
- journal article
- research article
- Published by Taylor & Francis in Molecular Physics
- Vol. 26 (5) , 1147-1167
- https://doi.org/10.1080/00268977300102371
Abstract
Results are given of Zeeman and microwave induced delayed phosphorescence experiments which determine the relative activities of the three zero-field spin components in the phosphorescence of benzene. The results allow one to decide which of the mechanisms proposed by Albrecht are responsible for the intensity of some of the most prominent bands in the phosphorescence spectrum. It is confirmed that vibronic coupling in the triplet manifold plays the dominant role for the phosphorescence bands that involve e 2g vibrations and it follows that the phosphorescence in these bands is almost purely out-of-plane polarized. Our results indicate that spin-orbit coupling occurs via the same mechanism as in other aromatic hydrocarbons.Keywords
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