Unveiling photon-photon coupling induced transparency and absorption

TL;DR

This paper develops a theoretical and numerical framework for understanding photon-photon coupling induced transparency and absorption, demonstrating control over these phenomena through system parameters with applications in optical switching and quantum information.

Contribution

It introduces the concepts of coupling induced transparency and absorption, providing analytical models and numerical validation for controlling light propagation in hybrid resonator systems.

Findings

Demonstrated level repulsion and attraction corresponding to CIT and CIA

Validated theoretical models with numerical simulations of SRR-ELC systems

Showed controlled transition between CIT and CIA by adjusting dissipation rates

Abstract

This study presents the theoretical foundations of an analogous electromagnetically induced transparency (EIT) and absorption (EIA) which we are referring as coupling induced transparency (CIT) and absorption (CIA) respectively, along with an exploration of the transition between these phenomena. We provide a concise phenomenological description with analytical expressions for transmission spectra and dispersion elucidating how the interplay of coherent and dissipative interactions in a coupled system results in the emergence of level repulsion and attraction, corresponding to CIT and CIA, respectively. The model is validated through numerical simulations using a hybrid system comprising a split ring resonator (SRR) and electric inductive-capacitive (ELC) resonator in planar geometry. We analyse two cases while keeping ELC parameters constant; one involving a dynamic adjustment of the SRR size with a fixed split gap, and the other entailing a varying gap while maintaining a constant SRR size. Notably, in the first case, the dispersion profile of the transmission signal demonstrates level repulsion, while the second case results in level attraction, effectively showcasing CIT and CIA, respectively. These simulated findings not only align with the theoretical model but also underscore the versatility of our approach. Subsequently, we expand our model to a more general case, demonstrating that a controlled transition from CIT to CIA is achievable by manipulating the dissipation rate of individual modes within the hybrid system, leading to either coherent or dissipative interactions between the modes. The results provide a pathway for designing hybrid systems that can control the group velocity of light, offering potential applications in the fields of optical switching and quantum information technology.