Abstract
Abstract Light-matter strong coupling is defined when the coupling strength exceeds the losses in the system, whereas ultrastrong coupling is not simply strong coupling with even larger coupling strength. Instead, ultrastrong coupling regime arises when the coupling strength is comparable to the transition frequency in the system. At present, ultrastrong light-matter interactions have been achieved in superconducting circuits, semiconductor polaritons, and organic molecules, where these systems are typically at the micrometer scale. In this work, we investigated ultrastrong coupling in a nanoparticle plexcitonic system, i.e. a single gold nanocube coated with quantum emitters and positioned on a gold film. We observed a normalized coupling rate η ~ 0.12 to the antenna mode in such coated nanocube-on-mirror (c-NCoM) configuration at the multilayer emitter level. In contrast to the gap mode that squeezes all the optical fields into the gap region, the antenna mode in c-NCoM provides multiple exterior hot spots at the upper corners of the nanocube, which can be exploited for qubit entanglement within a single nanocube. The concurrence between adjacent emitters is estimated up to 0.6. This theoretical study establishes a promising route toward building a scalable quantum network using single plexcitonic nanocubes as quantum nodes.
Highlights
The definitions of weak, strong, and ultrastrong coupling compare the light-matter coupling strength g with different parameters
We investigated ultrastrong coupling in a nanoparticle plexcitonic system, i.e. a single gold nanocube coated with quantum emitters and positioned on a gold film
We have demonstrated ultrastrong coupling in a single coated nanocube-on-mirror (c-NCoM) plexcitonic system, which supports antenna mode but has been overlooked
Summary
The definitions of weak, strong, and ultrastrong coupling compare the light-matter coupling strength g with different parameters. Xiong et al.: Ultrastrong coupling in single plexcitonic nanocubes involves the interactions between plasmon-polaritons and molecular excitons Such system would take advantage of (i) extremely confined mode volume of plasmonic cavity and (ii) giant transition dipole moment of organic molecules, providing a possibility to reduce the overall system size to nanometer scale. Due to the small gap between the metal nanoparticle (e.g. cube and sphere) and the metal film (i.e. the mirror), light can be extremely concentrated down to picometer scale [10, 22,23,24], bringing about unparalleled progresses in a single photon source [25, 26], strong coupling [16, 27,28,29,30], and quantum entanglement [31] These pioneering studies of NPoM are mostly focused on gap plasmons. NCoM configuration is shown to be a good platform that allows QEs to strongly couple to different cavity modes simultaneously
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