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The demonstration of high-efficiency coherent microwave-to-optics conversion could push atomic transducers closer to practical applications in quantum technologies.
A photonic anomalous Floquet insulator is emulated in a silicon photonic chip. Up to four-photon topologically protected entangled states are generated in a monolithically integrated emitter in ambient conditions through four-wave mixing on top of the edge modes of the insulator.
Attosecond-gated interferometry is developed by combining sub-cycle temporal gating and extreme-ultraviolet interferometry. By measuring the electron’s relative phase and amplitude under a tunnelling barrier, the quantum nature of the electronic wavepacket is identified.
A custom-designed metasurface for sample illumination and light collection in optical coherence tomography overcomes the usual trade off in lateral resolution and depth of field.
Researchers exploit Rayleigh waves and associated dynamic strains to control exciton transport in the weak coupling regime at room temperature. The findings may pave the way for new types of excitonic device for applications ranging from communications to energy.
The formation of ultra-short dissipative quadratic solitons is realized using optical parametric amplification at low pump energies and in the presence of substantial temporal walk-off between the pump and signal.
Twin-field (TF) quantum key distribution (QKD) over a secure distance of 833.8 km is demonstrated even in the finite-size regime. To this end, an optimized four-phase TF-QKD protocol and a high-speed low-noise TF-QKD system are developed.
Third-harmonic Mie scattering optical activity from suspensions of semiconductor (CdTe) nanostructured helices is observed, opening ways for chiroptical characterization of semiconductor and other chiral non-metallic particles in volumes potentially of the order of 10–17 m3.
A theoretical study of the time dependence of backscattering enhancements is presented, where strongly scattering media present a directional memory for time-varying signals even when the direct input signal has long decayed, providing opportunities for controlling the energy storage in interfaces and release of energy in random media for memory or enhanced coupling applications.
Photogalvanic effect in silicon nitride microresonators enables reconfigurable quasi-phase-matching for efficient and tunable second-harmonic generation.