Degenerate parametric down-conversion facilitated by exciton-plasmon polariton states in nonlinear plasmonic cavity

TL;DR

This paper investigates degenerate parametric down-conversion in a nonlinear plasmonic cavity with quantum emitters, revealing phase transitions, exciton-plasmon polaritons, and unique scaling laws for SP-QE interactions.

Contribution

It introduces a quantum model for DPDC in plasmonic cavities, highlighting new polariton states and a linear scaling of SP-QE interaction with emitter number, differing from traditional models.

Findings

Identification of a phase transition between normal and lasing states.

Prediction of exciton-plasmon polaritons involving two-SP quanta.

Discovery of linear scaling of SP-QE interaction with emitter number.

Abstract

We study the effect of degenerate parametric down-conversion (DPDC) in an ensemble of two-level quantum emitters (QEs) coupled via near-field interactions to a single surface plasmon (SP) mode of a nonlinear plasmonic cavity. For this purpose, we develop a quantum driven-dissipative model capturing non-equilibrium dynamics of the system in which incoherently pumped QEs have transition frequency tuned near the second-harmonic response of the SPs. Considering the strong coupling regime, i.e., the SP-QE interaction rate exceeds system dissipation rates, we find a critical SP-QE coupling attributed to the phase transition between normal and lasing steady states. Examining fluctuations above the system's steady states, we predict new elementary excitations, namely, the exciton-plasmon polaritons formed by the two-SP quanta and single-exciton states of QEs. The contribution of two-SP quanta results in the linear scaling of the SP-QE interaction rate with the number of QEs, ${\cal N}_o$, as opposed to the $\sqrt{{\cal N}_o}$-scaling known for the Dicke and Tavis-Cummings models. We further examine how SP-QE interaction scaling affects the polariton dispersions and power spectra in the vicinity of the critical coupling. For this purpose, we compare the calculation results assuming a finite ensemble of QEs and the model thermodynamic limit. The calculated power spectra predict an interplay of coherent photon emission by QEs near the second-harmonic frequency and correlated photon-pair emission at the fundamental frequency by the SPs (i.e., the photonic DPDC effect).