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Strong effective photon–photon interactions (Kerr-like optical nonlinearity) via the Rydberg blockade phenomenon in Cu2O-microcavity achieved under pulsed resonant excitation enabling fundamental studies of strongly correlated polaritonic states and quantum optical applications.
Hybrid Rayleigh-Brillouin-Raman distributed sensing system: Coded pulse pairs are employed for simultaneously measuring vibration, strain and temperature distributions, through an optimized detection scheme of Rayleigh, Brillouin, and Raman scatterings.
The integration between vertical-cavity surface-emitting lasers and metasurfaces has been demonstrated to enable on-chip high-angle illumination for high-contrast microscopy, providing a versatile illumination module for biophotonics and life-science applications.
We propose a new type of classical optical convolutional neural network by introducing the optical correlation. Such a network can exhibit “quantum speedup”like the quantum neural networks.
We demonstrate a high-performance single-photon source based on a monolithic FP microcavity, and the thin-film microcavity structure facilitates effective strain transduction.
We not only confirmed the superfluorescence effect, but also demonstrated the phase transition to cooperative exciton-polariton condensation. This was achieved by applying a regulatory dimension of light field.
Through the fine regulation of Förster and Dexter energy transfer, we managed triplet excitons, and the intensity ratio between thermally activated delayed fluorescence and room-temperature phosphorescence exhibited a great change.
Free-electron decoherence produced by electron coupling to radiation constitutes a quantum-physics macroscopic phenomenon that enables nondestructive sensing of distant objects
We discuss the recent progress on the dynamic control of tip-induced light-matter interactions, especially for the low dimensional quantum materials. This review is divided into three parts based on the type of tip-induced control, i.e., gap control of tip-cavity, tip-pressure control, and near-field polarization control.
Nonlocal metasurfaces with spatially varying geometries are modeled using a generalized coupled mode theory that operates in real space, enabling rapid numerical prototyping and insightful modeling of their spectro-spatial features.
The proposed visual remote sensing platform utilizes geometric phase encoding of stimuli-responsive cholesteric liquid crystal polymers to generate intuitive image signals, showcasing its proof of concept by real-time humidity monitoring.