6533b874fe1ef96bd12d6038

RESEARCH PRODUCT

Quantification of spatial inhomogeneity in perovskite solar cells by hyperspectral luminescence imaging

Gilbert El-hajjeHenk J. BolinkCristina MomblonaJorge ÁVilaJean-françois GuillemolesJean-françois GuillemolesLaurent LombezLidón Gil-escrigThomas GuillemotMichele Sessolo

subject

PhotonMaterials sciencePhotoluminescenceRenewable Energy Sustainability and the Environmentbusiness.industryOpen-circuit voltageEnergy conversion efficiencyHyperspectral imaging02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnology01 natural sciencesPollution0104 chemical sciencesOpticsNuclear Energy and EngineeringEnvironmental ChemistryOptoelectronics0210 nano-technologyLuminescencebusinessAbsolute scalePerovskite (structure)

description

Vacuum evaporated perovskite solar cells with a power conversion efficiency of 15% have been characterized using hyperspectral luminescence imaging. Hyperspectral luminescence imaging is a novel technique that offers spectrally resolved photoluminescence and electroluminescence maps (spatial resolution is 2 micrometer) on an absolute scale. This allows, using the generalized Planck’s law, the construction of absolute maps of the depth-averaged quasi-Fermi level splitting (Δμ), which determines the maximum achievable open circuit voltage (Voc) of the solar cells. In a similar way, using the generalized reciprocity relations the charge transfer efficiency of the cells can be obtained from the hyperspectral images. Very strong inhomogeneity, both in quasi-Fermi level splitting (Δμ) and in charge transfer efficiency, are found in these vacuum deposited perovskite solar cells. This implies that these efficient solar cells are still far from perfect as many areas in the device do not or only partially participate in the photon to electron conversion processes.

yearjournalcountryeditionlanguage
2016-01-01Energy & Environmental Science
https://doi.org/10.1039/c6ee00462h