Numerical FDTD simulations demonstrate that geometry-tuned plasmonic hollow nanocavities enable selective enhancement of A or B exciton photoluminescence in monolayer MoS2 with enhancements up to 143.85-fold and peak intensity ratios improved by 2.4 times over bare material.
Controlled -reflectance surfaces with film -coupled colloidal nanoantennas
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Geometry-Controlled Exciton Selectivity in Monolayer MoS2 Using Plasmonic Hollow Nanocavities
Numerical FDTD simulations demonstrate that geometry-tuned plasmonic hollow nanocavities enable selective enhancement of A or B exciton photoluminescence in monolayer MoS2 with enhancements up to 143.85-fold and peak intensity ratios improved by 2.4 times over bare material.