Aarhus University Seal

Phenyl radical, cation, and anion. The triplet-singlet gap and higher excited states of the phenyl cation

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaperJournal articleResearchpeer-review

  • Athanassios Nicolaides, Australian National University
  • ,
  • David M. Smith, Australian National University
  • ,
  • F. Jensen
  • Leo Radom, Australian National University
High-level ab initio molecular orbital calculations have been carried out for the phenyl cation (1), the phenyl radical (2), and the phenyl anion (3). Our best estimate for the heat of formation (ΔH(f298)) of the phenyl radical is 340 kJ mol, corresponding to 476 kJ mol for the 298 K C-H bond dissociation energy in benzene. The calculated ΔH(f298) of the phenyl anion is 224 kJ mol, leading to an electron affinity for the phenyl radical of 116 kJ mol, and a gas-phase acidity for benzene of 1671 kJ mol. The ground state of the phenyl cation is found to be a singlet (1-A,ΔH(f298) = 1134 kJ mol), with the triplet (1-B, ΔH(f298) = 1237 kJ mol) lying significantly higher in energy (by 103 kJ mol). The energies of the 1-A and 1-B states of the phenyl cation at the phenyl radical geometry are much closer, but 1-A remains the energetically lowest electronic state. The essentially isoenergetic 1-A and 1-A states lie about 25 kJ mol higher in energy than 1-B, while 1-B is nearly 60 kJ mol higher in energy. The implications of these results with respect to recent spectroscopic studies of the phenyl radical and the role of the triplet phenyl cation in the dissociation of benzene cation are discussed.
Original languageEnglish
JournalJournal of the American Chemical Society
Pages (from-to)8083-8088
Number of pages6
Publication statusPublished - 1997
Externally publishedYes

See relations at Aarhus University Citationformats

ID: 55283301