Measurement-induced entanglement in Tomonaga-Luttinger liquids is universal, conformally invariant, and arises from Born-rule averaging over conformally invariant boundary conditions in the CFT.
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Introduces resource theories for asynchronous port-based teleportation with free classical and quantum pre-processing, computes tight fidelity bounds for isotropic, graph, and symmetrized EPR states, and proves the strongest model equals any one-way protocol in surpassing the classical teleportation
Authors propose a low-optical-depth fusion-based photonic quantum computing architecture using quantum-dot emitters, adaptive repeat-until-success fusions, and time-bin qubits, with resource estimates and error-threshold simulations for fault tolerance.
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Measurement-Induced Entanglement in Conformal Field Theory
Measurement-induced entanglement in Tomonaga-Luttinger liquids is universal, conformally invariant, and arises from Born-rule averaging over conformally invariant boundary conditions in the CFT.
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A resource theory of asynchronous quantum information processing
Introduces resource theories for asynchronous port-based teleportation with free classical and quantum pre-processing, computes tight fidelity bounds for isotropic, graph, and symmetrized EPR states, and proves the strongest model equals any one-way protocol in surpassing the classical teleportation
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Practical blueprint for low-depth photonic quantum computing with quantum dots
Authors propose a low-optical-depth fusion-based photonic quantum computing architecture using quantum-dot emitters, adaptive repeat-until-success fusions, and time-bin qubits, with resource estimates and error-threshold simulations for fault tolerance.