Efficient
Polymer Solar Cells by Lithium Sulfonated Polystyrene as a Charge
Transport Interfacial Layer
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Abstract
In this paper, we
report the highly efficient bulk heterojunction (BHJ) polymer solar
cells (PSCs) with an inverted device structure via utilizing an ultrathin
layer of lithium sulfonated polystyrene (LiSPS) ionomer to reengineer
the surface of the solution-processed zinc oxide (ZnO) electron extraction
layer (EEL). The unique lithium-ionic conductive LiSPS contributes
to enhanced electrical conductivity of the ZnO/LiSPS EEL, which not
only facilitates charge extraction from the BHJ active layer but also
minimizes the energy loss within the charge transport processes. In
addition, the organic–inorganic LiSPS ionomer well circumvents
the coherence issue of the organic BHJ photoactive layer on the ZnO
EEL. Consequently, the enhanced charge transport and the lowered internal
resistance between the BHJ photoactive layer and the ZnO/LiSPS EEL
give rise to a dramatically reduced dark saturation current density
and significantly minimized charge carrier recombination. As a result, the inverted BHJ PSCs
with the ZnO/LiSPS EEL exhibit an approximatively 25% increase in
power conversion efficiency. These results indicate our strategy provides
an easy, but effective, approach to reach high performance inverted
PSCs