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πσ* excited states in molecular photochemistry

Research output: Contribution to journalArticle

Original languageEnglish
Pages (from-to)1218-1238
Number of pages21
JournalPhysical Chemistry Chemical Physics
Volume12
Issue number6
DOIs
DatePublished - 14 Feb 2010

Abstract

The last few years have seen a surge in interest (both theoretical and experimental) in the photochemistry of heteroaromatic molecules (e. g. azoles, phenols), which has served to highlight the importance of dissociative excited states formed by electron promotion to sigma* molecular orbitals. Such excited states-which, for brevity, are termed pi sigma* states in this Perspective article-may be populated by direct photo-excitation (though the transition cross-sections are intrinsically small), or indirectly, by non-adiabatic coupling from an optically 'bright' excited state (e. g. an excited state resulting from pi* <- pi excitation). The analogous pi sigma* excited states in prototypical hydride molecules like H2O and NH3 have long been recognised. They have served as test-beds for developing concepts like Rydbergisation, conical intersections (CIs) between potential energy surfaces, and for investigating the ways in which non-adiabatic couplings at such CIs influence the eventual photofragmentation dynamics. This Perspective article seeks to highlight the continuity of behaviour revealed by the earlier small molecule studies and by the more recent studies of heteroaromatic systems, and to illustrate the photochemical importance of pi sigma* excited states in many broad families of molecules. Furthermore, the dynamical influence of such excited states is not restricted to closed shell species; the Article concludes with a brief consideration of the consequences of populating sigma* orbitals in free radical species, in molecular cations, and in dissociative electron attachment processes.

    Research areas

  • Heterocyclic Compounds, Hydrocarbons, Aromatic, Nitriles, Organic Chemicals, Photochemical Processes

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