Frontiers of quantum physics

Macroscopic entanglement and phase transitions

Open Systems and Information Dynamics 14:1 (2007) 1-16

Authors:

J Anders, V Vedral

Abstract:

This paper summarises the results of our research on macroscopic entanglement in spin systems and free Bosonic gases. We explain how entanglement can be observed using entanglement witnesses which are themselves constructed within the framework of thermodynamics and thus macroscopic observables. These thermodynamical entanglement witnesses result in bounds on macroscopic parameters of the system, such as the temperature, the energy or the susceptibility, below which entanglement must be present. The derived bounds indicate a relationship between the occurrence of entanglement and the establishment of order, possibly resulting in phase transition phenomena. We give a short overview over the concepts developed in condensed matter physics to capture the characteristics of phase transitions in particular in terms of order and correlation functions. Finally we want to ask and speculate whether entanglement could be a generalised order concept by itself, relevant in (quantum induced) phase transitions such as BEC, and that taking this view may help us to understand the underlying process of high-T superconductivity. © Springer Science+Business Media B.V. 2007.

Composite Geometric Phase for Multipartite Entangled States

(2007)

Authors:

Mark Williamson, Vlatko Vedral

Spatial Entanglement From Off-Diagonal Long Range Order in a BEC

(2007)

Authors:

Libby Heaney, Janet Anders, Dagomir Kaszlikowski, Vlatko Vedral

How much of one-way computation is just thermodynamics?

(2007)

Authors:

Janet Anders, Damian Markham, Vlatko Vedral, Michal Hajdušek

Optomechanical entanglement between a movable mirror and a cavity field.

Phys Rev Lett 98:3 (2007) 030405

Authors:

D Vitali, S Gigan, A Ferreira, HR Böhm, P Tombesi, A Guerreiro, V Vedral, A Zeilinger, M Aspelmeyer

Abstract:

We show how stationary entanglement between an optical cavity field mode and a macroscopic vibrating mirror can be generated by means of radiation pressure. We also show how the generated optomechanical entanglement can be quantified, and we suggest an experimental readout scheme to fully characterize the entangled state. Surprisingly, such optomechanical entanglement is shown to persist for environment temperatures above 20 K using state-of-the-art experimental parameters.