2016
DOI: 10.1103/physrevb.94.125406
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Modified emission of extended light emitting layers by selective coupling to collective lattice resonances

Abstract: We demonstrate that the coupling between light emitters in extended polymer layers and modes supported by arrays of plasmonic particles can be selectively enhanced by accurate positioning of the emitters in regions where the electric field intensity of a given mode is maximized. The enhancement, which we measure to reach up to 70%, is due to the improved spatial overlap and coupling between the optical mode and emitters. This improvement of the coupling leads to a modification of the emission spectrum and the … Show more

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Cited by 63 publications
(63 citation statements)
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“…Therefore, the strong modification of the spectral shape is caused by the modification of the emission rate of Si-QDs due to the coupling with surface plasmons in the plasmonic substrates. 37 Similar data obtained for 641 nm excitations are summarized in the supplementary material (Fig. S4).…”
Section: Resultssupporting
confidence: 69%
“…Therefore, the strong modification of the spectral shape is caused by the modification of the emission rate of Si-QDs due to the coupling with surface plasmons in the plasmonic substrates. 37 Similar data obtained for 641 nm excitations are summarized in the supplementary material (Fig. S4).…”
Section: Resultssupporting
confidence: 69%
“…[21], reproduced with permission from APS), (b) hexagonal symmetry made of aluminum nanoparticles with pitch size of 475 (Ref. [62], reproduced with permission from APS), and (c) rectangular symmetry made of silver nanoparticles with pitch sizes of 380 and 200 nm (Ref. [63], reproduced with permission from OSA).…”
Section: Surface Lattice Resonancesmentioning
confidence: 99%
“…15 SLRs arise from the coherent radiative coupling of LSPs of individual nanoparticles with diffractive modes propagating in the plane of the array, the so-called Rayleigh anomalies, [16][17][18] and are characterized by a strong suppression of losses (higher quality factor) with respect to individual nanoparticle LSPs, at the expense of a less confined electromagnetic field (larger mode volume). 16,19,20 As hybrid modes arising from a coherent coupling of LSPs, SLRs can maintain the strong EM field enhancement typical of plasmonic nanoparticles, 21,22 while simultaneously extending over the whole lattice area. PEPs in 2D lattices have shown peculiar features due to the unique dispersion of SLRs, [23][24][25][26] which make them similar to exciton polaritons in semiconductor microcavities.…”
Section: Abstract: Polaritons Plasmonics Plexcitons Bose-eistein Cmentioning
confidence: 99%