Polymer solar cells based on diphenylmethanofullerenes with reduced sidechain length

Diphenylmethanofullerenes (DPMs) show interesting properties as acceptors in polymer bulk heterojunction solar cells due to the high open circuit voltages they generate compared to their energy levels. Here we investigate the effect of reducing the alkane sidechain length of the DPMs from C-12 to C-6 in the properties of the solar cell. This change leads to an increase in the electron mobility, thus allowing for a lower fullerene content, which in turn results in an increase in the short circuit current and, finally, in an increase in the efficiency of the device (from 2.3 to 2.6%) due to the higher concentration of the more absorbing polymer in the film. Atomic force microscopy images and external quantum efficiencies suggest the absence of crystallization of the fullerene to be at the origin of the slightly reduced performance of DPMs versus the standard fullerene [6,6]-phenyl-C-61-butyric acid methyl ester, implying that higher efficiencies could be possible with this class of fullerenes.