Reduction criterion of separability and limits for a class of distillation protocolsQuantum entanglementSeparability of mixed states: necessary and sufficient conditionsRealistic noise-tolerant randomness amplification using finite number of devices.Partial quantum information.The second laws of quantum thermodynamics.Simple scheme for encoding and decoding a qubit in unknown state for various topological codes.Quantum communication complexity advantage implies violation of a Bell inequalitySharp transitions in low-number quantum dots Bayesian magnetometryPort-based teleportation in arbitrary dimension.Fundamental limitations for quantum and nanoscale thermodynamics.Local indistinguishability: more nonlocality with less entanglement.Randomness Amplification under Minimal Fundamental Assumptions on the Devices.No Quantum Realization of Extremal No-Signaling Boxes.Limitations on the Evolution of Quantum Coherences: Towards Fully Quantum Second Laws of Thermodynamics.Unbounded Violation of Quantum Steering Inequalities.Resource theory of quantum states out of thermal equilibrium.Generalized teleportation and entanglement recycling.Efficient Quantum Pseudorandomness.Global information balance in quantum measurements.Direct estimations of linear and nonlinear functionals of a quantum state.Locking entanglement with a single qubit.Are the laws of entanglement theory thermodynamical?Mixed-State Entanglement and Distillation: Is there a “Bound” Entanglement in Nature?A Decoupling Approach to the Quantum CapacityQuantum Coding Theorem from Privacy and DistinguishabilityQuantum State Merging and Negative InformationQuantification of quantum correlation of ensembles of statesLocal versus nonlocal information in quantum-information theory: Formalism and phenomenaCommon Origin of No-Cloning and No-Deleting Principles Conservation of InformationDual entanglement measures based on no local cloning and no local deletingDistillation Protocols: Output Entanglement and Local Mutual InformationLocally Accessible Information: How Much Can the Parties Gain by Cooperating?Rates of asymptotic entanglement transformations for bipartite mixed states: Maximally entangled states are not specialLocal Information as a Resource in Distributed Quantum SystemsThe entanglement of purificationAmplifying the Randomness of Weak Sources Correlated With DevicesLocal Random Quantum Circuits are Approximate Polynomial-DesignsExponential Decay of Correlations Implies Area LawAn area law for entanglement from exponential decay of correlations
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P50
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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Michał Horodecki
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