Polaritonic coherent perfect absorption based on strong critical coupling between quasi-bound state in the continuum and exciton

TL;DR

This paper demonstrates how gap-perturbed dimerized gratings based on WS2 can achieve strong light-matter coupling and polaritonic coherent perfect absorption, advancing nanophotonic device performance.

Contribution

It introduces a novel method to control strong coupling and coherent absorption using gap perturbations in WS2-based gratings, with potential applications in light-emitting devices.

Findings

Achieved a Rabi splitting energy of 0.235 eV indicating strong coupling.

Demonstrated polaritonic coherent perfect absorption via two-port excitation.

Showed that gap perturbation controls the Q-factor of quasi-BICs.

Abstract

Enhancement of light-matter interactions is of great importance for many nanophotonic devices, and one way to achieve it is to feed energy perfectly to the strongly coupled system. Here, we propose gap-perturbed dimerized gratings based on bulk WS2 for flexible control of the strong coupling between quasi-bound state in the continuum (quasi-BIC) and exciton. The simulation results show that when a gap perturbation is introduced into the system resulting in the Brillouin zone folding, BIC transforms into quasi-BIC whose quality factor (Q-factor) is related to the value of gap perturbation. The strong coupling results in the anti-crossover behavior of the absorption spectra, and thus a Rabi splitting energy of 0.235 eV is obtained. Temporal coupled-mode theory is employed to analyze the strong coupling system, and the absorption of the system could be enhanced, by modulating the damping rate of quasi-BIC to make the system satisfy the strong critical coupling condition. Furthermore, polaritonic coherent perfect absorption is achieved by using the two-port source excitation. This work could provide ideas for enhancing light-matter interactions and a promising prospect for polariton-based light-emitting or lasing devices.