Programmable nonlinear bosonic circuits can deterministically produce phased-comb states that serve as a scalable bosonic quantum error-correcting code with near-optimal performance against boson loss.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
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quant-ph 3years
2026 3verdicts
UNVERDICTED 3representative citing papers
Photon addition and subtraction enhance Gaussian-source heralded generation of dual-rail Bell, GHZ, and W states with improved fidelity and success probability.
Engineered non-Gaussian coherence serves as a thermodynamic resource that optimizes quantum battery performance beyond Gaussian states for Gaussian charger profiles under unitary dynamics.
citing papers explorer
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Deterministic generation of grid states with programmable nonlinear bosonic circuits
Programmable nonlinear bosonic circuits can deterministically produce phased-comb states that serve as a scalable bosonic quantum error-correcting code with near-optimal performance against boson loss.
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Heralded entangled state generation enhanced by photon addition and subtraction
Photon addition and subtraction enhance Gaussian-source heralded generation of dual-rail Bell, GHZ, and W states with improved fidelity and success probability.
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Engineered non-Gaussian Coherence as a Thermodynamic Resource for Quantum Batteries
Engineered non-Gaussian coherence serves as a thermodynamic resource that optimizes quantum battery performance beyond Gaussian states for Gaussian charger profiles under unitary dynamics.