Abstract
Localized surface plasmon (LSP) coupling with many radiators are investigated. The LSP is generated by excitation of laser or electron beam on the random Ag nano particles (NPs) and arrayed ones embedded in the p-GaN of green LEDs. They couple with the excitons or radiative recombination in the quantum well (QW) and electron beam, which enhance or suppress the luminescence of the radiators. The photoluminescence (PL) intensity of periodic Ag NPs can get as much as 4.5 times higher than that of bare LED. In addition to the periodic structure, the morphology of Ag NPs also affects the localized SP (LSP) resonance intensity and light scattering efficiency. In the finite difference time domain (FDTD) simulation, five x-polarized dipoles are approximated to five quantum wells. Considering the interaction between the five dipoles and their feedback effect on LSP, the enhancement effect of SP dipole coupling with Ag NPs is amplified and the energy dissipation is reduced. The enhancement of cathodoluminescence (CL) was also found in green LEDs with Ag NPs. The three-body model composed of two orthogonal dipoles and an Ag NP is used for 3D FDTD simulation. The LSP-QWs coupling effect is separated from the electron beam (e-beam)-LSP-QW system by linear approximation. Under the excitation of electron beam, the introduction of z-dipole greatly reduces the energy dissipation. In the cross-sectional sample, z-polarized dipoles in QWs show more coupling strength to the dipole and quadrupole modes of LSP. The perturbation theory is used to separate the LSP coupling effects to x-dipole and z-dipole. At last, the resonator and the antenna effects are discussed for LSP coupling at different positions to the Ag NP.
Highlights
Surface plasmon (SP) can be coupled with excitons in radiators or photons in free space, and can be applied to high-efficiency, high-speed light-emitting diodes (LEDs) and color conversion [1,2,3,4]
In 1999, Gontijo et al predicted that when SP was resonantly excited in metal nanostructures, the spontaneous emission rate (SER) of the radiator could be increased by more than 1000 times, and its evanescent field had an impact on the radiator [5]
By exciting the SP gap mode of nano patch antenna (NPA), the SER of Ru dye is increased by 1000 times, and the quantum efficiency remains above 50% [6]
Summary
Surface plasmon (SP) can be coupled with excitons in radiators or photons in free space, and can be applied to high-efficiency, high-speed light-emitting diodes (LEDs) and color conversion [1,2,3,4]. The vertical dipole will produce highintensity near-field for the Ag NPs, which will significantly affect the coupling between LSP and QWs. The dipoles representing quantum wells and e-beam are in-plane and out-plane, respectively. The perpendicular dipoles corresponding to electron beam provide a new chance to study the LSP coupling to many radiators. Many radiators coupled with an LSP mechanism on different LED structures were studied by photoluminescence (PL), CL measurements and three-dimensional (3D) finite difference time domain (FDTD) simulation [51]. The coupling between LSP and many radiators is summarized, and the new metallic NPs/LED structure is predicted
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