Teixeira, CristinaCristinaTeixeiraSpinelli, Pier PaoloPier PaoloSpinelliCastriotta, Luigi AngeloLuigi AngeloCastriottaMüller, DavidDavidMüllerÖz, SenolSenolÖzAndrade, LuísaLuísaAndradeMendes, AdélioAdélioMendesCarlo, Aldo diAldo diCarloWürfel, UliUliWürfelWojciechowski, KonradKonradWojciechowskiForgács, DávidDávidForgács2022-09-152022-09-152022https://publica.fraunhofer.de/handle/publica/42552510.1002/adfm.2022067612-s2.0-85134736275Perovskite Solar Cells (PSCs) are well known for their high efficiencies under 1 sun (AM1.5G), however, PSC can also generate power by harvesting the low-light available indoors. Here, three flexible PSC architectures are presented for indoor applications: with a metal electrode aiming for high efficiency; carbon electrode aiming for high stability and compatibility with large-scale production; and hole transport material (HTM)-free carbon for simplifying the fabrication process. A maximum efficiency of 30.9% (30.0%) under 1000 lux (200 lux) is obtained for a PSC with gold electrode. A maximum efficiency of 25.4% (24.7%) and 23.1% (22.3%) is obtained for the carbon devices with and without HTM, respectively, under 1000 lux (200 lux). To the best of the author's knowledge, the efficiency values presented here for a device with a carbon-based electrode, with and without HTM, are the record values for a flexible PSC at indoor light conditions. Furthermore, the HTM-free carbon device kept 84% of its initial efficiency after 1000 h at MPPT and lost virtually no performance after 1000 h at 85 °C. Also, non-encapsulated devices of all configurations withstood 1600 h in air with a maximum loss in efficiency of 6%.encarbon electrodesflexible substratesindoor photovoltaicsperovskite solar cellscharge extractionindoor applicationsjournal article