We report on a new class of optical antennas that shorten the excited-state lifetime of optical emitters down to 100 fs in a broad spectral range, while maintaining quantum efficiencies as high as 80%. We combine metal nanoparticles with dielectric structures and exploit concepts from plasmonics and cavity quantum electrodynamics to maximize the local density of states and suppress dissipation losses in the metal. Our findings bring about the prospect of single-photon sources at the mu W power level and promise significant impact on other research fields, including photophysics, ultrafast plasmonics, and Raman spectroscopy.
Metallodielectric Optical Antennas for Ultrabright Single-Photon Sources
Agio Mario;
2012
Abstract
We report on a new class of optical antennas that shorten the excited-state lifetime of optical emitters down to 100 fs in a broad spectral range, while maintaining quantum efficiencies as high as 80%. We combine metal nanoparticles with dielectric structures and exploit concepts from plasmonics and cavity quantum electrodynamics to maximize the local density of states and suppress dissipation losses in the metal. Our findings bring about the prospect of single-photon sources at the mu W power level and promise significant impact on other research fields, including photophysics, ultrafast plasmonics, and Raman spectroscopy.File in questo prodotto:
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