Abstract
Standard and inverted configuration small molecule OPV cells incorporating bathocuproine (BCP) as electron transport and exciton blocking layer is investigated, demonstrating that 2 mm2 standard and inverted cells display a maximum performance for BCP thicknesses of 10 nm and 1.5 nm, respectively. The reason for the different optimum BCP thicknesses for the two device configurations is the BCP-metal complex formed between the Ag electrode and the BCP layer in the standard configuration OPV devices. Interestingly, at optimum BCP thicknesses, the inverted OPV cells outperform the standard devices. Upon up-scaling of the device area of the cells from 2 mm2 to 10 and 100 mm2, device failure becomes prominent for the inverted OPV cells, due to aggregation of the evaporated BCP layer on the ITO surface. This demonstrates that although BCP can be adopted for efficient ETL in inverted configuration OPV devices on small scale, it is not suitable for device up-scaling due to severely decreasing device yields. In this work, a possible solution where an ultrathin layer of C70 is evaporated between the ITO and BCP layer is proposed. It is demonstrated that the proposed solution holds a strong potential to minimize the device failures of the BCP based inverted OPV cells to a significant extent, while maintaining good device performances.
Highlights
Organic photovoltaics (OPVs), being eco-friendly and easy-to-produce, are considered to be a prominent sustainable energy source for the future
We assess the impact of BCP as electron transport and exciton blocking layer on the performance of standard and inverted planar heterojunction OPV devices consisting of Tetraphenyldibenzoperiflanthene (DBP) as donor and Fullerene (C70) as acceptor molecules
The performance of standard and inverted DBP and C70 based OPV devices incorporating BCP as electron transport layer was investigated while up-scaling the device areas from 2 to 10 and 100 mm[2]
Summary
Organic photovoltaics (OPVs), being eco-friendly and easy-to-produce, are considered to be a prominent sustainable energy source for the future. Fullerenes demonstrate excellent electron mobilities, efficient charge extraction in OPV devices still requires an Electron Transport and Exciton Blocking Layer (ETL and EBL, respectively) with well-matched energy levels, that is integrated between the electron acceptor layer and the metal cathode, in order to minimize any interface losses[4,5,6,7,8,9]. BCP facilitates efficient electron transport in standard configuration OPV devices[17,18,19,20] This transport efficiency is ascribed to the presence of metal-BCP complexes that form when the metal, here Ag, is evaporated on top of the BCP layer. The proposed method improves the overall device yield as well as the performance of the fabricated 100 mm[2] inverted OPV devices
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