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Strong coupling between colloidal quantum dots and a microcavity with hybrid structure at room temperature

Zhen Zhen, Siyue Jin, Jie Ren, Hai-Yao Liang, Xingsheng Xu

2022Photonics Research13 citationsDOI

Abstract

The interaction between light and matter has always been the focus of quantum science, and the realization of truly strong coupling between an exciton and the optical cavity is a basis of quantum information systems. As a special semiconductor material, colloidal quantum dots have fascinating optical properties. In this study, the photoluminescence spectra of colloidal quantum dots are measured at different collection angles in microcavities based on hybrid refractive-index waveguides. The photon bound states in the continuum are found in the low–high–low refractive-index hybrid waveguides in the appropriate waveguide width region, where the photoluminescence spectra of colloidal quantum dots split into two or more peaks. The upper polaritons and lower polaritons avoid resonance crossings in the systems. The Rabi splitting energy of 96.0 meV can be obtained. The observed phenomenon of vacuum Rabi splitting at room temperature is attributed to the strong coupling between quantum dots and the bound states in the continuum.

Topics & Concepts

Quantum dotPhotoluminescencePolaritonBound stateExcitonCondensed matter physicsPhotonicsQuantum opticsRefractive indexCavity quantum electrodynamicsPhysicsPhotonOptical microcavityMaterials scienceOptoelectronicsQuantum dot laserQuantumMolecular physicsSemiconductorOpticsQuantum mechanicsOpen quantum systemLaserSemiconductor laser theoryStrong Light-Matter InteractionsPhotonic Crystals and ApplicationsSemiconductor Quantum Structures and Devices
Strong coupling between colloidal quantum dots and a microcavity with hybrid structure at room temperature | Litcius