6533b7d1fe1ef96bd125c4b4
RESEARCH PRODUCT
Plasmonic nanostructures for light trapping in thin-film solar cells
Manuel J. MendesSeweryn MorawiecIsodiana CrupiFrancesco PrioloFrancesco Priolosubject
Materials scienceCondensed Matter Physic02 engineering and technologySettore ING-INF/01 - Elettronica7. Clean energy01 natural sciencesSilver nanoparticlelaw.inventionNanoparticlelawPhotovoltaics0103 physical sciencesSolar cellMechanics of MaterialGeneral Materials Sciencesubwavelength nanostructuresDewettingThin filmSurface plasmon resonancePlasmonThin film solar cell010302 applied physicsthin film solar cellsbusiness.industryMechanical EngineeringSelf-assemblyself-assemblyLocalized surface plasmon resonance021001 nanoscience & nanotechnologyCondensed Matter PhysicsphotovoltaicsMechanics of MaterialsOptoelectronicsPlasmonic-enhanced light trappingSubwavelength nanostructurenanoparticlesMaterials Science (all)0210 nano-technologybusinessPhotovoltaicLocalized surface plasmondescription
Abstract The optical properties of localized surface plasmon resonances (LSPR) sustained by self-assembled silver nanoparticles are of great interest for enhancing light trapping in thin film photovoltaics. First, we report on a systematic investigation of the structural and the optical properties of silver nanostructures fabricated by a solid-state dewetting process on various substrates. Our study allows to identify fabrication conditions in which circular, uniformly spaced nanoparticles are obtainable. The optimized NPs are then integrated into plasmonic back reflector (PBR) structures. Second, we demonstrate a novel procedure, involving a combination of opto-electronic spectroscopic techniques, allowing for the quantification of useful and parasitic absorption in thin photovoltaic absorber deposited on top of the PBR. We achieve a significant broadband useful absorption enhancement of 90% for 0.9 µm thick μc-Si:H film and demonstrate that optical losses due to plasmonic scattering are insignificant below 730 nm. Finally, we present a successful implementation of a plasmonic light trapping scheme in a thin film a-Si:H solar cell. The quantum efficiency spectra of the devices show a pronounced broadband enhancement resulting in remarkably high short circuit current densities (Jsc).
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-01-01 |