Energy transfer enhancement by oxygen perturbation of spin-forbidden electronic transitions in aromatic systems

Triplet-triplet energy transfer in multicomponent organic systems is usually entirely ascribed to a Dextertype mechanism involving only short-range donor/acceptor interactions. We demonstrate that the presence of molecular oxygen introduces a perturbation to the electronic structure of one of the involved moieties which can induce a large increase in the spin-forbidden transition oscillator strength so that the otherwise negligible Forster contribution dominates the overall energy transfer rate.