Abstract
We report the enhancement of organic photodetector (OPD) performance through the incorporation of CsPbBr(3) perovskite nanocrystals (PNCs) into P3HT:PCBM devices. The optimized device (HPD_01) exhibits a maximum responsivity of 0.083 A/W and a specific detectivity of ~4.7 × 10(10) Jones, and a minimum NEP of 5.2 × 10(-12) W·Hz(-1/2) at the self-powered operating point (V ≈ 0 V), outperforming the nanoparticle-free reference. Frequency- and distance-dependent measurements under visible light communication conditions demonstrate that the optimized device maintains strong signal detection up to 1 MHz and at distances exceeding 15 cm. Notably, the external quantum efficiency spectra reveal an additional contribution in the 450-575 nm range, which is absent in the reference device. This enhancement is consistent with a radiative absorption-reemission energy-transfer mechanism, supported by quantitative spectral overlap analysis showing that 99.5% of the PNC photoluminescence falls within the 450-575 nm EQE enhancement window and that the maximum differential EQE gain occurs at 519 nm-only 2 nm from the PNC emission peak. Our results suggest that controlled PNC incorporation enables efficient optical energy coupling, leading to high-sensitivity, fast-response OPDs suitable for optical communication applications.