Abstract
Confining light to scales beyond the diffraction limit, quantum plasmonics supplies an ideal platform to explore strong light-matter couplings. The light-induced localized surface plasmons (LSPs) on the metal-dielectric interface acting as a quantum bus have wide potential in quantum information processing; however, the loss nature of light in the metal hinders their application. Here we propose a mechanism to make the reversible energy exchange and the multipartite quantum correlation of a collective of quantum emitters (QEs) mediated by the LSPs persistent. Via investigating the quantized interaction between the QEs and the LSPs supported by a spherical metal nanoparticle, we find that the diverse signatures of the quantized QE-LSP coupling in the steady state, including the complete decay, population trapping, and persistent oscillation, are essentially determined by the different number of bound states formed in the energy spectrum of the QE-LSP system. Enriching our understanding on the light-matter interactions in a lossy medium, our result is instructive in the design of quantum devices using plasmonic nanostructures.
Highlights
Hybrid systems composed of metal nanoparticles (MNPs) and quantum emitters (QEs) have drawn intense attention in physics, chemistry, and materials and life sciences [1,2,3,4,5]
One can see that P(t ) tends to a nonzero value when r = 9.0 nm, which represents a stable population trapping in the system, while when r = 8.0 nm, P(t ) tends to a lossless oscillation with a constant frequency, which is quite like the Rabi oscillation [54] and represents a persistent energy exchange among QEs caused by the QE-localized surface plasmons (LSPs) interaction
We have proposed a mechanism to overcome the loss effect of LSPs in metal by investigating the exact dynamics of N QEs coupled to LSPs supported by a MNP
Summary
Hybrid systems composed of metal nanoparticles (MNPs) and quantum emitters (QEs) have drawn intense attention in physics, chemistry, and materials and life sciences [1,2,3,4,5]. Fascinating effects, including the superradiance of an ensemble of dipoles [15], the surface plasmon amplification by stimulated emission of radiation [16], the quantum statistics control of photons [17], and the suppression of quantum fluctuations of light [18], have been found These effects have led to a wide application of the LSPs in quantum information processing and quantum device designing. It has been found that a QE residing near the metal is quenched by its decay through the nonradiative electromagnetic modes absorbed by the metal [20,21,22,23] Such quenching hampers the complete quantum control in plasmonic systems, where a persistent quantum coherence is of importance. Among the QEs plays a constructive role in applying the LSPs as a quantum bus in quantum information processing
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
