Spin-orbit coupling in aromatic hydrocarbons. The radiative triplet lifetime of naphthalene

The phosphorcscencc hncshapc of rnplcr cluncrs IS analyscd usmg Ihc duccr spm-orbn couplmg mechamsms. Tnplsr spmquultwtlon and spin-orbit routes arc calculated for any conligur~~ron of cluster. Tlus and Ihe consrdcralron ofmolccults with one subMuted 13C allow us to understand bcttcr the napthalene

The assignment of 3nn\* or 'nn' character to the lowest triplet states of aromatic carbonyl compounds can be made from their EPR spectra on the basis of spin-orbit induced changes to both the fiie-structure parameters and the g-values.

The triplet lifetime of aromatic hydrocarbons in liquid solution is relativc:jr short compared with the lifetime in a rigid solution. Until now this difference has been exphined by an impurity quenching mechanism. An alternative explanation is given, assuming quenching of a triplet molecule by B sin

The origin of the Tl state of naphthalene in a p-dibromobenzene host crystal is shown to be the strongest line in the spectrum at 20720.9 cm -1 . The vibronic activity of the naphthalene phosphorescence indicates that a spin-orbit coupling mechanism different from the one vibronically induced in an

Optically induced magnelizallon has been observed in polycrys~als and solulions or various aromatic carbonyls, quinones. and aza-aromalics at room lemperalure using a simple pickupxoil detector. The magnetic-Lcld dependence of the mngmtude or Ihe induced magncGadon provided clear evidence of the cre