Curing the vulnerable heterointerface viaorganic-inorganic hybrid hole transporting bilayers for efficient inverted perovskite solar cells

To promote the practices of perovskite photovoltaics, it requires to develop efficient perovskite solar cells (PVSCs) standing long-time operation under the adverse environments. Herein, we demonstrate that the tailor-made conjugated polymers as conductive adhesives stabilized the originally redox-reactive heterointerface between perovskite and metal oxide, facilitating the access of efficient and stable inverted PVSCs. It was revealed that bithiophene and phenyl alternating conjugated polymers with partial glycol chains atop of the metal oxide layer has resulted in effective organic-inorganic hybrid hole transporting bilayers, which allow maintaining efficient hole extraction and transport, meanwhile preventing halide migration to directly contact with the nickel oxide (NiOx) layer. As a result, the corresponding inverted PVSCs with the organic-inorganic hole transporting bilayers have achieved an excellent power conversion efficiency of 23.22%, outperforming 20.65% of bare NiOx-based devices. Moreover, the encapsulated PVSCs with organic-inorganic bilayers exhibited the excellent photostability with 91% of the initial efficiency after 1000-h one-sun equivalent illumination in ambient conditions. Overall, this work provides new insights into stabilizing the vulnerable heterointerface for perovskite solar cells.