Integrated manufacturing of REciclable multi-material COmposites for the TRANSport sector
Flexible Indoor Perovskite Solar Cells by in Situ Bottom?up Crystallization Modulation and Interfacial Passivation
A robust perovskite?buried interface is pivotal for achieving high?performance flexible indoor photovoltaics as it significantly influences charge transport and extraction efficiency. Herein, we introduce a molecular bridge strategy utilizing sodium 2?cyanoacetate (SZC) additive at the perovskite?buried interface to simultaneously achieve in situ passivation of interfacial defects and bottom?up crystallization modulation, resulting in high performance flexible indoor photovoltaic applications. Supported by both theoretical calculations and experimental evidences, we illustrate how SZCs serve as molecular bridges, establishing robust bonds between SnO2 transport layer and perovskite, mitigating oxygen vacancy defects and under?coordinated Pb defects at interface during flexible fabrication. This, in turn, enhances interfacial energy level alignment and facilitates efficient carrier transport. Moreover, our in situ investigation of perovskite crystallization dynamics reveals bottom?up crystallization modulation, extending perovskite growth at the buried interface and influencing subsequent surface recrystallization. This results in larger crystalline grains and improved lattice strain of the perovskite during flexible fabrication. Finally, the optimized flexible solar cells achieve an impressive efficiency exceeding 41% at 1000 lux, with a fill factor as high as 84.32%. The concept of the molecular bridge represents a significant advancement in enhancing the performance of perovskite?based flexible indoor photovoltaics for the upcoming era of the Internet of Things (IoT).This article is protected by copyright. All rights reserved
» Publication Date: 20/03/2024
This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement Nº 768737
