Litcius/Paper detail

Controlling light emission from semiconductor nanoplatelets using surface chemistry

Michael W. Swift, Alexander L. Efros, Steven C. Erwin

2024Nature Communications13 citationsDOIOpen Access PDF

Abstract

Semiconductor nanoplatelets are atomically flat nanocrystals which emit light with high spectral purity at wavelengths controlled by their thickness. Despite their technological potential, efforts to further sharpen the emission lines of nanoplatelets have generally failed for unknown reasons. Here, we demonstrate theoretically that the linewidth is controlled by surface chemistry-specifically, inhomogeneities in the ligand layer on the nanoplatelet surface lead to a spatially fluctuating potential that localizes excitons. This localization leads to increased scattering and optical broadening. Importantly, localization also reduces the rate of radiative emission. Our model explains the observed linewidth and predicts that a more uniform ligand layer will sharpen the lines and increase the emission rates. These findings demonstrate that light emission from nanoplatelets can be controlled by optimizing their surface chemistry, an important advantage for their eventual use in optical technologies.

Topics & Concepts

Laser linewidthRadiative transferSemiconductorExcitonOptoelectronicsMaterials scienceWavelengthScatteringLight emissionSurface (topology)Emission spectrumNanotechnologyOpticsSpectral lineLaserPhysicsCondensed matter physicsAstronomyGeometryMathematicsQuantum Dots Synthesis And PropertiesNanocluster Synthesis and ApplicationsGold and Silver Nanoparticles Synthesis and Applications
Controlling light emission from semiconductor nanoplatelets using surface chemistry | Litcius