Prof Vlatko Vedral FInstP

Quantum Correlations in Mixed-State Metrology

Physical Review X 1:2 (2011) 1-9

Authors:

K Modi, H Cable, M Williamson, V Vedral

Abstract:

We analyze the effects of quantum correlations, such as entanglement and discord, on the efficiency of phase estimation by studying four quantum circuits that can be readily implemented using NMR techniques. These circuits define a standard strategy of repeated single-qubit measurements, a classical strategy where only classical correlations are allowed, and two quantum strategies where nonclassical correlations are allowed. In addition to counting space (number of qubits) and time (number of gates) requirements, we introduce mixedness as a key constraint of the experiment.We compare the efficiency of the four strategies as a function of the mixedness parameter. We find that the quantum strategy gives ffiffiffiffi N p enhancement over the standard strategy for the same amount of mixedness. This result applies even for highly mixed states that have nonclassical correlations but no entanglement.

Physical interpretation of the Wigner rotations and its implications for relativistic quantum information

(2011)

Authors:

Pablo L Saldanha, Vlatko Vedral

Topological order in 1D Cluster state protected by symmetry

(2011)

Authors:

Wonmin Son, Luigi Amico, Vlatko Vedral

Quantumness and Entanglement Witnesses

(2011)

Authors:

Paolo Facchi, Saverio Pascazio, Vlatko Vedral, Kazuya Yuasa

Natural mode entanglement as a resource for quantum communication

AIP Conference Proceedings 1363 (2011) 299-302

Authors:

L Heaney, V Vedral

Abstract:

Natural particle-number entanglement resides between spatial modes in coherent ultracold atomic gases. However, operations on the modes are restricted by a superselection rule that forbids coherent superpositions of different particle numbers. This would seemingly prevent mode entanglement from being used as a resource for quantum communication. Here I demonstrate that mode entanglement of a single massive particle can be used for dense coding despite the superselection rule if both parties share a coherent reservoir. © 2011 American Institute of Physics.