Prof Vlatko Vedral FInstP

Crucial role of quantum entanglement in bulk properties of solids

Physical Review A - Atomic, Molecular, and Optical Physics 73:1 (2006)

Authors:

C Brukner, V Vedral, A Zeilinger

Abstract:

We demonstrate that two well-established experimental techniques of condensed-matter physics, neutron-diffraction scattering and measurement of magnetic susceptibility, can be used to detect and quantify macroscopic entanglement in solids. Specifically, magnetic susceptibility of copper nitrate (CN) measured in 1963 cannot be described without presence of entanglement. A detailed analysis of the spin correlations in CN as obtained from neutron-scattering experiment from 2000 provides microscopic support for this interpretation and gives the value for the amount of entanglement. We present a quantitative analysis resulting in the critical temperature of 5 K in both, completely independent, experiments below which entanglement exists. © 2006 The American Physical Society.

Entanglement-assisted orientation in space

International Journal of Quantum Information 4:2 (2006) 365-370

Authors:

C Brukner, N Paunković, T Rudolph, V Vedral

Abstract:

We demonstrate that quantum entanglement can help separated individuals in making decisions if their goal is to find each other in the absence of any communication between them. We derive a Bell-like inequality that the efficiency of every classical solution for our problem has to obey, and demonstrate its violation by the quantum efficiency. This proves that no classical strategy can be more efficient than the quantum one. © 2006 World Scientific Publishing Company.

Entangled world: The fascination of quantum information and computation

NATURE 441:7096 (2006) 935-935

Magnetic susceptibility as a macroscopic entanglement witness

New Journal of Physics 7 (2005) 1-8

Authors:

M Wieśniak, V Vedral, C Brukner

Abstract:

We show that magnetic susceptibility can reveal spin entanglement between individual constituents of a solid, while magnetization describes their local properties. We then show that magnetization and its variance (equivalent to magnetic susceptibility for a wide class of systems) satisfy complementary relation in the quantum-mechanical sense. It describes sharing of (quantum) information in the solid between spin entanglement and local properties of its individual constituents. Magnetic susceptibility is shown to be a macroscopic (thermodynamical) spin entanglement witness that can be applied without complete knowledge of the specific model (Hamiltonian) of the solid. © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft.

Detecting entanglement with a thermometer

(2005)

Authors:

Janet Anders, Dagomir Kaszlikowski, Christian Lunkes, Toshio Ohshima, Vlatko Vedral