Leaving Forster Resonance Energy Transfer Behind: Nanometal Surface Energy Transfer Predicts the Size-Enhanced Energy Coupling between a Metal Nanoparticle and an Emitting Dipole

The interaction of a fluorescent molecule with a gold nanoparticle is complex and can lead to excited-state enhancement or quenching. Many attempts have been made to explain the observed interaction when in close proximity to the metal surface; yet no single model has been capable of explaining the observations. In this work, we show that by accurately describing the interaction in terms of an induced image dipole modified within the gold nanoparticle by the size-dependent changes in absorptivity and dielectric constant, the oscillator interaction can be fully described in terms of a surface-moderated interaction. Comparison of experimental and theoretical data confirms the validity of the model for a selected range of separation distances, nanoparticle radii, and fluorescent molecule selection. The results of the study illustrate the importance of nonradiative pathways for modifying the decay of a fluorescent molecule by coupling to the image dipole, thus providing a firm understanding of the reported variance in behavior for an emitting species in close proximity to nanometal surfaces. A more significant impact of the results is the ability to apply nanometal surface energy transfer methods as a molecular ruler to probe physical questions at much greater distances (>400 angstrom) than previously achievable.