1,625 research outputs found

    Deterministic Dense Coding and Faithful Teleportation with Multipartite Graph States

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    We proposed novel schemes to perform the deterministic dense coding and faithful teleportation with multipartite graph states. We also find the sufficient and necessary condition of a viable graph state for the proposed scheme. That is, for the associated graph, the reduced adjacency matrix of the Tanner-type subgraph between senders and receivers should be invertible.Comment: 10 pages, 1 figure;v2. discussions improve

    Polydipsia-induced hyponatremia and status epilepticus in a schizophrenia patient: A case report from the emergency department

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    AbstractRelated to severe hyponatremia, various symptoms, such as confusion, vomiting, changes in mental state, status epilepticus, and a variety of conscious disturbances are sometimes seen in the emergency department (ED) but seldom recognized as water intoxication in the early stages. Status epilepticus is an emergent and life-threatening condition if not diagnosed and managed promptly and efficiently. The authors reported a case of a 31-year-old woman with history of schizophrenia with poor drug compliance. The compulsive drinking of more than 15,000mL of water per day for 4 days resulted in intermittent episodes of vomiting and seizures and she was sent to our ED by ambulance. Water intoxication with severe hyponatremia ([Na+]=112mEq/L) was diagnosed and hypertonic sodium supplements and airway protection were then offered. Detailed history taking and early detection of hyponatremia is crucial to prevent fatal complications of water intoxication. Emergency physicians should be suspicious of hyponatremia from water intoxication in psychiatric patients with neurologic symptoms during the observation period in the ED

    Multipartite Entanglement Measures and Quantum Criticality from Matrix and Tensor Product States

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    We compute the multipartite entanglement measures such as the global entanglement of various one- and two-dimensional quantum systems to probe the quantum criticality based on the matrix and tensor product states (MPSs/TPSs). We use infinite time-evolving block decimation (iTEBD) method to find the ground states numerically in the form of MPSs/TPSs, and then evaluate their entanglement measures by the method of tensor renormalization group (TRG). We find these entanglement measures can characterize the quantum phase transitions by their derivative discontinuity right at the critical points in all models considered here. We also comment on the scaling behaviors of the entanglement measures by the ideas of quantum state renormalization group transformations.Comment: 22 pages, 11 figure

    Symmetry Protected Quantum State Renormalization

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    Symmetry protected topological (SPT) phases with gapless edge excitations have been shown to exist in principle in strongly interacting bosonic/fermionic systems and it is highly desirable to find practical systems to realize such phases through numerical calculation. A central question to be addressed is how to determine the SPT order in the system given the numerical simulation result while no local order parameter can be measured to distinguish the phases from a trivial one. In the tensor network approach to simulate strongly interacting systems, the quantum state renormalization algorithm has been demonstrated to be effective in identifying the intrinsic topological orders. Here we show that a modified algorithm can identify SPT orders by extracting the fixed point entanglement pattern in the ground state wave function which is essential for the existence of SPT order. The key to this approach is to add symmetry protection to the quantum state renormalization process and we demonstrate the effectiveness of this algorithm with the example of AKLT states in both 1D and 2D

    Size, Temperature, and Strain-Rate Dependence on Tensile Mechanical Behaviors of Ni 3

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    This study focuses on exploring the mechanical properties and nonlinear stress-strain behaviors of monoclinic Ni3Sn4 single crystals under uniaxial tensile test and also their size, temperature, and strain-rate dependence through constant temperature molecular dynamics (MD) simulation using Berendsen thermostat. The deformation evolution of the Ni3Sn4 atomic nanostructure during the tensile test is observed. In addition, the tensile yield strains of various Ni3Sn4 single crystals at different strain rates and temperatures are characterized through unloading process. At last, by way of linear regression analysis, the corresponding normal elastic stiffness constants are approximated and then compared with the literature theoretical data. The radial distribution function analysis shows that Ni3Sn4 single crystal in a one-dimensional nanowire configuration would become a highly disordered structure after thermal equilibration, thereby possessing amorphous-like mechanical behaviors and properties. The initial elastic deformation of Ni3Sn4 single crystal is governed by the reconfiguration of surface atoms, and its deformation evolution after further uniaxial tensile straining is characterized by Ni=Sn bond straightening, bond breakage, inner atomic distortion, cross-section shrinking, and rupture. The calculated normal elastic constants of Ni3Sn4 single crystal are found to be consistent with the literature theoretical data
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