Prof Vlatko Vedral FInstP

Wigner rotations and an apparent paradox in relativistic quantum information

PHYSICAL REVIEW A 87:4 (2013) ARTN 042102

Authors:

Pablo L Saldanha, Vlatko Vedral

Topological order in 1D Cluster state protected by symmetry

Quantum Information Processing 11:6 (2012) 1961-1968

Authors:

W Son, L Amico, V Vedral

Abstract:

We demonstrate how to construct the Z2 × Z2 global symmetry which protects the ground state degeneracy of cluster states for open boundary conditions. Such a degeneracy ultimately arises because the set of stabilizers do not span a complete set of integrals of motion of the cluster state Hamiltonian for open boundary conditions. By applying control phase transformations, our construction makes the stabilizers into the Pauli operators spanning the qubit Hilbert space from which the degeneracy comes. © Springer Science+Business Media, LLC 2011.

Unifying Typical Entanglement and Coin Tossing: On Randomization in Probabilistic Theories

Communications in Mathematical Physics 316:2 (2012) 441-487

Authors:

MP Müller, OCO Dahlsten, V Vedral

Abstract:

It is well-known that pure quantum states are typically almost maximally entangled, and thus have close to maximally mixed subsystems. We consider whether this is true for probabilistic theories more generally, and not just for quantum theory. We derive a formula for the expected purity of a subsystem in any probabilistic theory for which this quantity is well-defined. It applies to typical entanglement in pure quantum states, coin tossing in classical probability theory, and randomization in post-quantum theories; a simple generalization yields the typical entanglement in (anti)symmetric quantum subspaces. The formula is exact and simple, only containing the number of degrees of freedom and the information capacity of the respective systems. It allows us to generalize statistical physics arguments in a way which depends only on coarse properties of the underlying theory. The proof of the formula generalizes several randomization notions to general probabilistic theories. This includes a generalization of purity, contributing to the recent effort of finding appropriate generalized entropy measures. © 2012 Springer-Verlag Berlin Heidelberg.

Classical Vs Quantum correlations in composite systems

(2012)

Authors:

Luigi Amico, Sougato Bose, Vladimir E Korepin, Vlatko Vedral

The classical-quantum boundary for correlations: Discord and related measures

Reviews of Modern Physics 84:4 (2012)

Authors:

K Modi, A Brodutch, H Cable, T Paterek, V Vedral

Abstract:

One of the best signatures of nonclassicality in a quantum system is the existence of correlations that have no classical counterpart. Different methods for quantifying the quantum and classical parts of correlations are among the more actively studied topics of quantum-information theory over the past decade. Entanglement is the most prominent of these correlations, but in many cases unentangled states exhibit nonclassical behavior too. Thus distinguishing quantum correlations other than entanglement provides a better division between the quantum and classical worlds, especially when considering mixed states. Here different notions of classical and quantum correlations quantified by quantum discord and other related measures are reviewed. In the first half, the mathematical properties of the measures of quantum correlations are reviewed, related to each other, and the classical-quantum division that is common among them is discussed. In the second half, it is shown that the measures identify and quantify the deviation from classicality in various quantum-information- processing tasks, quantum thermodynamics, open-system dynamics, and many-body physics. It is shown that in many cases quantum correlations indicate an advantage of quantum methods over classical ones. © 2012 American Physical Society.