A carbon nanotube microtoroid platform with Tomonaga-Luttinger liquid protection achieves chiral spin-momentum locking for nonreciprocal spin-photon interfaces with cooperativities above 100 and chiral contrast over 20 dB.
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Monolithic quantum scaling fails beyond 10^5-10^6 qubits due to classical latency outpacing coherence, requiring modular LOCC-based architectures with time-aware scheduling protocols.
A robust protocol based on Hong-Ou-Mandel interference for generating and measuring arbitrary high-dimensional time-bin quantum states, demonstrated with high-fidelity tomographies of 2D and 3D states.
citing papers explorer
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A Universal Topological Platform for Nonreciprocal Spin-Photon Interface in Solid-State Quantum Networks
A carbon nanotube microtoroid platform with Tomonaga-Luttinger liquid protection achieves chiral spin-momentum locking for nonreciprocal spin-photon interfaces with cooperativities above 100 and chiral contrast over 20 dB.
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Beyond Monolithic Scaling: Modularity and Heterogeneity as an Architectural Imperative for Utility-Scale Quantum Computing
Monolithic quantum scaling fails beyond 10^5-10^6 qubits due to classical latency outpacing coherence, requiring modular LOCC-based architectures with time-aware scheduling protocols.
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A robust approach for time-bin encoded photonic quantum information protocols
A robust protocol based on Hong-Ou-Mandel interference for generating and measuring arbitrary high-dimensional time-bin quantum states, demonstrated with high-fidelity tomographies of 2D and 3D states.