The use of a Marcus formulation to describe photo-induced electron transfer processes in the complex blends of conjugated polymers and fullerenes associated with organic photovoltaics is rare. The conventional approach considers the polymer and fullerene to form a type II band offset similar to a picture for two inorganic semiconductors. A motivation for this presentation is to ask whether this simple model is correct and only the energetics need be considered when examining the driving force for the photo-induced electron transfer process. Or whether a re-organization energy is also required to describe the effect and therefore an optimum driving force is required to realize high charge separation yields.

This presentation will describe two studies using a series of trifluoromethylfullerenes (TMFs) dispersed at low concentration in a conjugated polymer film or in a bilayer forming an interface with a layer of chiral-pure single-walled carbon nanotubes (SWCNTs). The fullerene series provides exquisite control over a wide range of reduction potentials of the fullerene, and can thus influence the driving force for photo-induced electron transfer studies. In both experiments, the use of the electrodeless technique of flash photolysis, time-resolved microwave conductivity (fp-TRMC) which provides a sensitive probe of the yield and kinetics of charges generated in both systems.