Boosting Photodetection via Plasmonic Coupling in Quasi-2D Mixed-n Ruddlesden-Popper Perovskite Nanostripes

Quasi-2D metal halide perovskites have emerged as a promising material for photodetection due to excellent optoelectronic properties, simple synthesis, and robust stability. Albeit, developing high-performance photodetectors based on low-dimensional quasi-2D metal halide perovskite nanoparticles remains challenging due to quantum and dielectric confinement effects. Several approaches have been employed to improve efficiency, with plasmonic nanostructures being among the most effective ones. The resonant energy transfer and coupling between plasmons and excitons play a vital role in enhancing device performance. Here, we demonstrate enhanced photodetection of quasi-2D perovskite nanostripes resulting from the incorporation of octadecanethiol (ODT) functionalized Ag nanostructure arrays (ANA). Using colloidal lithography, ANA were fabricated. Reflectance spectroscopy and finite element method (FEM) simulations show that ANA supports localised surface plasmon resonance (LSPR) modes that spectrally coincide with the absorption and emission band of the perovskite. This spectral overlap enables interesting coupling interactions between the excitons and plasmons. The ODT-functionalized ANA photodetectors exhibit weak to intermediate coupling, resulting in a photocurrent enhancement factor of 838 %. They achieve photoresponsivities of up to 70.41 mA W^-1, detectivities of 1.48*10^11 Jones and external quantum efficiencies of 21.55 %, which are approximately 10 times higher than those of the reference photodetector. We present an approach to optimize the plasmon-exciton coupling and non-radiative energy transfer for developing high-performance plasmonic-perovskite hybrid photodetectors.