Tunable plasmon-enhanced second-order optical nonlinearity in transition metal dichalcogenide nanotriangles

Abstract

The development of nanomaterials with a large nonlinear susceptibility is essential for nonlinear nanophotonics. We show that transition-metal-dichalcogenide (TMD) nanotriangles have a large effective second-order susceptibility [(2)] at mid-infrared to near-infrared frequencies owing to their broken centrosymmetry. (2) is calculated within the density-matrix formalism that accounts for dissipation and screening. (2) peaks in the vicinity of both two-photon resonances (specified by the geometry) and plasmon resonances (tunable via the carrier density). Aligning the resonances yields the values of (2) as high as 10-6 m/V. These findings underscore the potential of TMD nanotriangles for nonlinear nanophotonics, particularly second-harmonic generation.