Compositional engineering has led to dramatic improvements in hybrid perovskite-based solar cell stabilities and performance. Mixed cation perovskites have emerged as champion photovoltaic materials with power conversion efficiencies exceeding 22%.… Click to show full abstract
Compositional engineering has led to dramatic improvements in hybrid perovskite-based solar cell stabilities and performance. Mixed cation perovskites have emerged as champion photovoltaic materials with power conversion efficiencies exceeding 22%. However, there has been relatively little work done to explore local cation-related compositional inhomogeneities in mixed cation perovskite films. Such studies are necessary because hybrid perovskite optical properties and, consequently, their photovoltaic performance strongly depend on composition. Here, we perform spatially resolved, subdiffraction infrared photothermal heterodyne imaging measurements to probe cation-specific compositional distributions within FAxMA1–xPbI3 perovskite films. Our measurements reveal that these perovskites possess large compositional spatial heterogeneities with cation distributions varying on average ∼20% from expected ensemble stoichiometries. Correlated emission measurements show intrafilm emission energies differing by over...
               
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