Decoration of transition metal carbide nanoparticles on reduced graphene oxide for the efficient bulk heterojunction organic photovoltaics

Herein, we fabricated the bulk heterojunction organic photovoltaics (OPV) using the different hybrid composites doped novel combination of PBDB-T:PCBM/hybrid-nanostructures with the architecture of ITO/HTL/activelayer/LiF/Al. Structural and morphological characteristics were evidently established the formation of W2C@rGO and Mo2C@rGO composites by the simple chemical reduction process. The different concentrations of prepared nanocomposites were doped with polymer PBDB-T:PCBM matrix to modify the active layer properties in the OPV devices. The Mo2C@rGO and W2C@rGO (10 vol%) composites using tuned active realized the improved power conversion efficiency (PCE) of 6.98 and 6.84%, respectively which is quite high compared to the pure PBDB-T: PCBM active layer (PCE = 5.61%) and bare rGO (6.66%), Mo2C (6.43%) and W2C (6.20%) outcomes. The procured results explored that the W2C@rGO and Mo2C@rGO hybrid incorporated active layers facilitate the swift charge transport and extraction possibility to achieve the high efficiency photovoltaic devices.

Automated summary

In this study, bulk heterojunction organic photovoltaics (OPV) were fabricated using different hybrid composites doped with a novel combination of PBDB-T:PCBM/hybrid-nanostructures. The structure and morphology of the W2C@rGO and Mo2C@rGO composites were established through a simple chemical reduction process. The incorporation of Mo2C@rGO and W2C@rGO hybrid into the active layers resulted in significantly improved power conversion efficiency (PCE) of 6.98% and 6.84%, respectively, compared to pure PBDB-T:PCBM and other materials. These findings suggest that the hybrid incorporated active layers facilitate efficient charge transport and extraction, leading to high-efficiency photovoltaic devices.