Activating spin-forbidden transitions in molecules by the highly localized plasmonic field

Optical spectroscopy has been the primary tool to study the electronic structure of molecules. However the strict spin selection rule has severely limited its ability to access states of different spin multiplicities. Here we propose a new strategy to activate spin-forbidden transitions in molecules by introducing spatially highly inhomogeneous plasmonic field. The giant enhancement of the magnetic field strength resulted from the curl of the inhomogeneous vector potential makes the transition between states of different spin multiplicities naturally feasible. The dramatic effect of the inhomogeneity of the plasmonic field on the spin and symmetry selection rules is well illustrated by first principles calculations of C60. Remarkably, the intensity of singlet-triplet transitions can even be stronger than that of singlet-singlet transitions when the plasmon spatial distribution is comparable with the molecular size. This approach offers a powerful means to completely map out all excited states of molecules and to actively control their photochemical processes. The same concept can also be applied to study nano and biological systems.