Non-Hermitian transition matrices implemented on a silicon photonic processor drive arbitrary multimode optical fields to equal intensities and globally locked phase, with independently programmable synchronization rate and power throughput.
Decoherence-induced Multiphoton Interference
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abstract
Decoherence is usually deemed detrimental to quantum information processing. Its control and minimization require significant costs and operating overheads, constituting a major hurdle to commercialize quantum technology. Yet, quantum mechanics provides for counterintuitive, sometimes surprisingly useful, phenomena and effects associated with decoherence, leading to unusual practical utilities. Here we demonstrate such an example of fundamental interest and practical potential, where genuine quantum interference is created among multiple photons through their dissipative coupling to a shared reservoir. On a thin-film lithium niobate chip, we incoherently link two spontaneous parametric down-converters through a common, highly-lossy channel to create coherent multiphoton states. Our results show that faithful correlations can be established among two, three, and four photons, and tuned by shifting the relative phase between the driving pumps for the converters. This experiment highlights an under-explored territory in quantum science and technology, where loss and decoherence serve as resources, rather than adversaries, for quantum information processing.
fields
physics.optics 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
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Programmable Non-Hermitian Synchronization of Light on a Silicon Photonic Processor
Non-Hermitian transition matrices implemented on a silicon photonic processor drive arbitrary multimode optical fields to equal intensities and globally locked phase, with independently programmable synchronization rate and power throughput.