Polaritonic Critical Coupling in a Hybrid Quasi-Bound States in the Continuum Cavity-WS2 Monolayer System

Abstract

We theoretically propose and numerically demonstrate that perfect feeding of a polaritonic system with full electromagnetic energy under one-port beam incidence, referred to as polaritonic critical coupling, can be achieved in a hybrid dielectric metasurface-WS2 monolayer structure. Polaritonic critical coupling, where the critical coupling and strong coupling are simultaneously attained, is determined by the relative damping rates of the cavity resonance, γQ, provided by a symmetry-protected quasi-bound states in the continuum, and excitonic resonance of WS2 monolayer, γX. We reveal that the population of the polariton states can be tuned by the asymmetric parameter of the quasi-bound states in the continuum. Furthermore, polaritonic critical coupling is achieved in the designed system while γQ=γX and only strong coupling is achieved while γQ≠γX. This work enriches the study of polaritonic physics with controlled absorbance and may guide the design and application of efficient polariton-based light-emitting or lasing devices.

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