Prof Vlatko Vedral FInstP

Detection and engineering of spatial mode entanglement with ultra-cold bosons

(2009)

Authors:

J Goold, Libby Heaney, Th Busch, V Vedral

Quantum instability and edge entanglement in the quasi-long-range order

Physical Review A - Atomic, Molecular, and Optical Physics 79:2 (2009)

Authors:

W Son, L Amico, F Plastina, V Vedral

Abstract:

We investigate the buildup of quasi-long-range order in the XX chain with a transverse magnetic field at finite size. As the field is varied, the ground state of the system displays multiple level crossings producing a sequence of entanglement jumps. Using the partial fidelity and susceptibility, we study the transition to the thermodynamic limit and argue that the topological order can be described in terms of kink-antikink pairs and marked by edge spin entanglement. © 2009 The American Physical Society.

Entanglement and nonlocality of a single relativistic particle

(2009)

Authors:

Jacob Dunningham, Vlatko Vedral

Colloquium: The physics of Maxwell's demon and information

Reviews of Modern Physics 81:1 (2009) 1-23

Authors:

K Maruyama, F Nori, V Vedral

Abstract:

Maxwell's demon was born in 1867 and still thrives in modern physics. He plays important roles in clarifying the connections between two theories: thermodynamics and information. Here the history of the demon and a variety of interesting consequences of the second law of thermodynamics are presented, mainly in quantum mechanics, but also in the theory of gravity. Also highlighted are some of the recent work that explores the role of information, illuminated by Maxwell's demon, in the arena of quantum-information theory. © 2009 The American Physical Society.

A simple thermodynamical witness showing universality of macroscopic entanglement

Open Systems and Information Dynamics 16:2-3 (2009) 287-291

Abstract:

We show that if the ground state entanglement exceeds the total entropy of a given system, then this system is in an entangled state. This is a universal entanglement witness that applies to any physical system and yields a temperature below which we are certain to find some entanglement. Our witness is then applied to generic bosonic and fermionic many-body systems to derive the corresponding "critical" temperatures that have a very broad validity. © 2009 World Scientific Publishing Company.