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Issue 13, 2013
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TiO2nanowire electron transport pathways inside organic photovoltaics

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Abstract

Charge transport is one of the five main steps in the operation of organic photovoltaics, but achieving balanced hole and electron transport with high mobility has been challenging in devices. Here, we report improved charge transport in organic photovoltaics via incorporation of nanostructured inorganic electron transport materials into the active layers of devices. Co-depositing TiO2 nanowires with the organic active layer solution embeds the nanowires directly within active layers of the solar cell. The ability of these nanowires to transport electrons is compared with neat P3HT:PCBM active layers and also devices containing TiO2 nanotube aggregates. Incorporation of TiO2 nanowires yields a six-fold increase in the electron mobility relative to unmodified devices, leading to a 19% improvement in the power conversion efficiency. Lower energetic disorder of the film and more balanced charge transport are also observed upon incorporating TiO2 nanowires. These advantageous effects correlate with the TiO2 nanowire length.

Graphical abstract: TiO2 nanowire electron transport pathways inside organic photovoltaics

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Article information


Submitted
23 Jan 2013
Accepted
01 Feb 2013
First published
01 Feb 2013

Phys. Chem. Chem. Phys., 2013,15, 4566-4572
Article type
Paper

TiO2 nanowire electron transport pathways inside organic photovoltaics

P. Yang, D. K. Zhong, M. Yuan, A. H. Rice, D. R. Gamelin and C. K. Luscombe, Phys. Chem. Chem. Phys., 2013, 15, 4566
DOI: 10.1039/C3CP50325A

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