Faißt, JaredJaredFaißtList, MathiasMathiasListBaretzky, ClemensClemensBaretzkyBett, Andreas W.Andreas W.BettWürfel, UliUliWürfel2025-07-112025-07-112025https://publica.fraunhofer.de/handle/publica/48945210.1002/aenm.2025013482-s2.0-105008552752Measuring photoluminescence (PL) of free charge carriers under operation conditions is a valuable tool for characterizing solar cells. However, in organic solar cells, free charge carrier PL is typically obscured by the emission from non-dissociated excitons. To overcome this, an adaptation of the time-resolved PL measurement method is introduced that allows for the separate observation of the effects of applied voltage on the PL of excitons and free charge carriers. Using state-of-the-art D18:Y6 and PM6:Y6 organic solar cells (power conversion efficiencies: (Formula presented.) and (Formula presented.)), this study demonstrated: I) the determination of the implied voltage from free charge carrier PL under operation conditions providing insights into transport losses under steady-state and transient conditions, II) the construction of a PL-based current-implied voltage curve revealing implied efficiencies of (Formula presented.) and (Formula presented.); III) an estimation of the photogenerated current at the maximum power point by combining PL and electroluminescence measurements, showing a (Formula presented.) reduction compared to the short-circuit current, and IV) a discussion of possible origins of this reduction, including recombination due to limited transport, electrode-induced charges and field-dependent exciton dissociation. The introduced method thus provides a valuable diagnostic tool for identifying both transport and current losses in high-efficiency organic solar cells.enfalsecharge carrier transportfield-dependent current generationorganic solar cellpseudo current-voltage curvequasi-fermi-level splittingtransient photoluminescenceImplied Voltage and Current Characterization in Organic Solar Cells using Transient Photoluminescencejournal article