Affiliation:
1. Australian Research Council Centre of Excellence in Exciton Science Department of Chemical and Biological Engineering Monash University Clayton Victoria 3800 Australia
2. Australian Research Council Centre of Excellence in Exciton Science Department of Materials Science and Engineering Monash University Clayton Victoria 3800 Australia
3. Clarendon Laboratory Department of Physics University of Oxford Parks Road Oxford OX1 3PU United Kingdom
Abstract
AbstractThe efficiency of back‐contact perovskite solar cells has steadily increased over the past few years and now exceeds 11%, with interest in these devices shifting from proof‐of‐concept to viable technology. In order to make further improvements in the efficiency of these devices it is necessary to understand the cause of the low fill factor, low open‐circuit voltage (VOC), and severe hysteresis. Here a time‐dependent Suns‐Voc and Suns‐photoluminescence (PL) analysis are performed to monitor the transient ideality factor spatially. Two sets of quasi‐interdigitated back‐contact perovskite solar cells are studied; cells with and without a mesoporous TiO2 layer. Maps of the PL intensity and ideality factor resemble the periodic structure of the back‐contact electrodes and the transient behavior exhibit distinct features such as a temporary variation in the periodicity of the modulation, spatial phase shifting, and phase offsets. It is shown that the presence of the mesoporous layer greatly reduces recombination, increasing the VOC by 0.12 V. Coupled 2D time‐dependent drift‐diffusion simulations allow the experimental results to be modeled, and replicate the key features observed experimentally. They reveal that non‐uniform ion distribution along the transport layer interfaces can drastically alter the PL intensity and ideality factor throughout the device.
Funder
Australian Renewable Energy Agency
Australian Research Council
Subject
General Materials Science,Renewable Energy, Sustainability and the Environment
Cited by
7 articles.
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