Issue 1, 2016

Light emission in nanogaps: overcoming quenching

Abstract

Very large spontaneous-emission-rate enhancements (∼1000) are obtained for quantum emitters coupled with tiny plasmonic resonance, especially when emitters are placed in the mouth of nanogaps formed by metal nanoparticles that are nearly in contact. This fundamental effect of light emission at subwavelength scales is well documented and understood as resulting from the smallness of nanogap modes. In contrasts, it is much less obvious to figure out whether the radiation efficiency is high in these gaps, or if the emission is quenched by metal absorption especially for tiny gaps a few nanometers wide; the whole literature only contains scattered electromagnetic calculations on the subject, which suggest that absorption and quenching can be kept at a small level despite the emitter proximity to metal. Thus through analytical derivations in the limit of small gap thickness, it is our objective to clarify why quantum emitters in nanogap antennas offer good efficiencies, what are the circumstances in which high efficiency is obtained, and whether there exists an upper bound for the maximum efficiency achievable.

Graphical abstract: Light emission in nanogaps: overcoming quenching

Article information

Article type
Focus
Submitted
25 Aug 2015
Accepted
20 Oct 2015
First published
20 Oct 2015

Nanoscale Horiz., 2016,1, 11-13

Light emission in nanogaps: overcoming quenching

J. Yang, R. Faggiani and P. Lalanne, Nanoscale Horiz., 2016, 1, 11 DOI: 10.1039/C5NH00059A

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