Tuning a photonic-crystal bandgap in a driven Kerr microresonator switches the soliton spectrum between a uniform-power Mott-insulator comb and a non-uniform superfluid comb with phase coherence.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Demonstrates magneto-optical traps for all stable strontium isotopes using co-designed atomic beam slowing, PIC-met surface laser delivery, and integrated frequency-comb stabilization, advancing bulk-optics-free Sr optical clocks.
Numerical simulations demonstrate cavity solitons in fiber cavities as a reservoir for photonic neuromorphic computing, with Kelly waves improving performance on standard benchmarks.
citing papers explorer
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Nanophotonic control of collective many-body states in Kerr solitons
Tuning a photonic-crystal bandgap in a driven Kerr microresonator switches the soliton spectrum between a uniform-power Mott-insulator comb and a non-uniform superfluid comb with phase coherence.
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A scalable infrastructure for strontium optical clocks with integrated photonics
Demonstrates magneto-optical traps for all stable strontium isotopes using co-designed atomic beam slowing, PIC-met surface laser delivery, and integrated frequency-comb stabilization, advancing bulk-optics-free Sr optical clocks.
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Cavity Solitons as a Nonlinear Substrate for Photonic Neuromorphic Computing
Numerical simulations demonstrate cavity solitons in fiber cavities as a reservoir for photonic neuromorphic computing, with Kelly waves improving performance on standard benchmarks.