Frontiers of quantum physics

Increasing identical particle entanglement by fuzzy measurements

Physical Review A - Atomic, Molecular, and Optical Physics 72:6 (2005)

Authors:

D Cavalcanti, M França Santos, MO Terra Cunha, C Lunkes, V Vedral

Abstract:

We investigate the effects of fuzzy measurements on spin entanglement for identical particles, both fermions and bosons. We first consider an ideal measurement apparatus and define operators that detect the symmetry of the spatial and spin part of the density matrix as a function of particle distance. Then, moving on to realistic devices that can only detect the position of the particle to within a certain spread, it was surprisingly found that the entanglement between particles increases with the broadening of detection. © 2005 The American Physical Society.

Entanglement-assisted Orientation in Space

(2005)

Authors:

Caslav Brukner, Nikola Paunkovic, Terry Rudolph, Vlatko Vedral

Work extraction from tripartite entanglement

New Journal of Physics 7 (2005)

Authors:

V Viguié, K Maruyama, V Vedral

Abstract:

It has recently been shown that the work extractable from correlated bipartite quantum systems under an appropriate protocol can be used to distinguish entanglement from classical correlation. A natural question is now whether it can be generalized to multipartite systems. In this paper, we devise a protocol to distinguish the GHZ, the W, and separable states in terms of the thermodynamically extractable work under local operations and classical communication, and compare the results with those obtained from Mermin's inequalities. © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft.

Heat Capacity as A Witness of Entanglement

(2005)

Authors:

Marcin Wiesniak, Vlatko Vedral, Caslav Brukner

Thermodynamical cost of accessing quantum information

Journal of Physics A: Mathematical and General 38:32 (2005) 7175-7181

Authors:

K Maruyama, C Brukner, V Vedral

Abstract:

Thermodynamics is a macroscopic physical theory whose two very general laws are independent of any underlying dynamical laws and structures. Nevertheless, its generality enables us to understand a broad spectrum of phenomena in physics, information science and biology. Does thermodynamics then imply any results in quantum information theory? Taking accessible information in a system as an example, we show that thermodynamics implies a weaker bound on it than the quantum mechanical one (the Holevo bound). In other words, if any post-quantum physics should allow more information storage it could still be under the umbrella of thermodynamics. © 2005 IOP Publishing Ltd.