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Published online by Cambridge University Press: 31 January 2011
The performance of polymer-based photovoltaic devices is limited by several factors like high band-gap and low charge-carrier mobility, to name a few. Thicker active-layers have high optical absorption but the transport of carriers in them is inefficient. Thus the optimal thickness of the active-layers has to be determined carefully. This conflict can be resolved using a three-dimensional (3D) microscale textured grating shaped solar cell geometry. The solar cells in this study were fabricated on photoresist gratings to give them 3D texture required for enhanced light absorption. Introduction of texturing has a significant effect on over all power conversion efficiency of the devices. Grating based solar cell having 2 micron pitch showed improved power conversion efficiency over the flat solar cell. In addition to favorable guiding of optical modes, the improvement in efficiency is accomplished by homogenous coverage of the spin-coated active layer, which is a challenging process for non-flat surfaces. Uniform thickness in this study was facilitated by the sufficiently high pitch and low height of the underlying photoresist gratings.