Photovoltaic-thermoelectric (PV-TE) hybrid systems offer a platform for enhancing the energy conversion efficiency of photovoltaic devices. However, they still suffer from energy losses and limited efficiency improvements owing to underutilized parasitic thermal energy and electrical parameters mismatches between PV and TE components. Here, we presented a comprehensive theoretical analysis and simulation based on a PV-TE Thermo-Electrical Coupling Model, predicting that the maximum efficiency of the system could reach 60.34% with state-of-the-art PV and commercial TE technologies. Following this model, we fabricated hybrid systems with organic and perovskite solar cells coupled with thermoelectric cells, achieving record-high efficiencies of 34.85% and 42.03% at 298 K, and 43.16% and 50.28% at 313 K, respectively, under AM 1.5 G illumination, with optimal thermal utilization and current matching between series-connected PV and TE modules. This work highlights the potential of PV-TE hybrid systems and could offer guidance for designing higher-efficiency systems, driving future advancements in photovoltaics. Photovoltaic-thermoelectric (PV-TE) hybrid systems offer a platform for enhancing the energy conversion efficiency of photovoltaic devices. Here, the authors present solution-processed PV-TE hybrid systems optimized for heat utilization and current matching, experimentally demonstrating a maximum efficiency of 50.28%.
Yin et al. (Fri,) studied this question.