Unravelling the mystery of enhanced open-circuit voltages in nanotextured perovskite solar cells (2506.10691v2)

Abstract: Perovskite solar cells have reached power conversion efficiencies that rival those of established silicon photovoltaic technologies. Nanotextures in perovskite solar cells optimise light trapping and scattering, thereby improving optical absorption. In addition, nanotextures have been experimentally shown to enhance electronic performance, in particular, by increasing the open-circuit voltage $V_{\text{OC}}$ -- a phenomenon that, until now, has remained not fully understood. This study investigates the underlying reasons by combining multi-dimensional optical and charge-transport simulations for a single-junction perovskite solar cell. Our results reveal that the increased open-circuit voltage is not driven by optical effects but by the textured geometry itself. For voltages near $V_{\text{OC}}$, texturing one of the absorber/transport layer interfaces increases the imbalance between electron and hole densities in the absorber, thereby reducing Shockley-Read-Hall (SRH) recombination, which is the dominant loss mechanism in this study. While idealised solar cells benefit unconditionally from increasing texture height, in realistic cells there is an optimal texture height which maximizes the power conversion efficiency. These findings provide new insights into the opto-electronic advantages of texturing and offer guidance for the design of next-generation textured perovskite-based solar cells, light emitting diodes, and photodetectors.