Proposes emulating metric fluctuations' effect on fermion spin in a lattice (2+1)D massive gravity model via a minimal two-bosonic-mode system simulatable with atomic states in an optical cavity.
Cavity-based quantum networks with single atoms and optical photons
3 Pith papers cite this work. Polarity classification is still indexing.
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A time-bin multiplexing protocol generates parallel multipartite entanglement among N quantum nodes using a photon whose time-bin dimension stays independent of N.
Proposes using sum-frequency generation-based quantum frequency conversion combined with resonant confinement in ring resonators to bridge broadband flying qubits with narrowband quantum memories for long-range quantum networks.
citing papers explorer
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Probing metric fluctuations with the spin of a particle in a quantum simulation
Proposes emulating metric fluctuations' effect on fermion spin in a lattice (2+1)D massive gravity model via a minimal two-bosonic-mode system simulatable with atomic states in an optical cavity.
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Resource-efficient parallel entanglement generation for multinode quantum networks via time-bin multiplexing
A time-bin multiplexing protocol generates parallel multipartite entanglement among N quantum nodes using a photon whose time-bin dimension stays independent of N.
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Toward quantum interconnects featuring nanometer-to-picometer bandwidth compression and THz-range quantum frequency conversion
Proposes using sum-frequency generation-based quantum frequency conversion combined with resonant confinement in ring resonators to bridge broadband flying qubits with narrowband quantum memories for long-range quantum networks.