Monolithic Si3N4 platform achieves EPR fidelity 0.9875(3), HOM visibility 0.990(6), and four-photon GHZ fidelity 0.943(8) at 27 Hz—more than 100x prior silicon-photonic rates—using CMOS-compatible 150 mm wafer fabrication.
Atatüre, D
4 Pith papers cite this work. Polarity classification is still indexing.
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Plasma etch recipe produces photonic-grade diamond-on-insulator films from bonded SCD membranes and enables 5 nm resolution thickness mapping via colorimetry on standard microscope images.
Single quantum emitters in hBN enable independent dual sensing of temperature via ZPL position and magnetic field via ODMR.
Exciton polaritons in microcavities form synthetic photonic crystals with engineered band structures and interactions for exploring many-body physics from mean-field to quantum regimes.
citing papers explorer
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An ultralow-loss integrated photonic platform for discrete-variable quantum information processing
Monolithic Si3N4 platform achieves EPR fidelity 0.9875(3), HOM visibility 0.990(6), and four-photon GHZ fidelity 0.943(8) at 27 Hz—more than 100x prior silicon-photonic rates—using CMOS-compatible 150 mm wafer fabrication.
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Plasma Etch Process Optimization for Photonic-Grade Diamond-on-Insulator Substrates and Thickness Evaluation using Colorimetry
Plasma etch recipe produces photonic-grade diamond-on-insulator films from bonded SCD membranes and enables 5 nm resolution thickness mapping via colorimetry on standard microscope images.
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On chip, multifunctional quantum sensing using single spins in a van der Waals crystal
Single quantum emitters in hBN enable independent dual sensing of temperature via ZPL position and magnetic field via ODMR.
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Synthetic Polariton Matter in the solid state
Exciton polaritons in microcavities form synthetic photonic crystals with engineered band structures and interactions for exploring many-body physics from mean-field to quantum regimes.