Frontiers of quantum physics

Optomechanical to mechanical entanglement transformation

New Journal of Physics 10 (2008)

Authors:

G Vacanti, M Paternostro, GM Palma, V Vedral

Abstract:

We present a scheme for generating entanglement between two mechanical oscillators that have never interacted with each other by using an entanglement-swapping protocol. The system under study consists of a Michelson-Morley interferometer comprising mechanical systems embodied by two cantilevers. Each of them is coupled to a field mode via the radiation pressure mechanism. Entanglement between the two mechanical systems is set by measuring the output modes of the interferometer. We also propose a control mechanism for the amount of entanglement based on path-length difference between the two arms. © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft.

Second Quantized Kolmogorov Complexity

(2008)

Authors:

Caroline Rogers, Vlatko Vedral, Rajagopal Nagarajan

Entanglement in doped Resonating Valence Bond states

(2008)

Authors:

Ravishankar Ramanathan, Dagomir Kaszlikowski, Marcin Wiesniak, Vlatko Vedral

Quantum correlation without classical correlations.

Phys Rev Lett 101:7 (2008) 070502

Authors:

Dagomir Kaszlikowski, Aditi Sen De, Ujjwal Sen, Vlatko Vedral, Andreas Winter

Abstract:

We show that genuine multiparty quantum correlations can exist on its own, without a supporting background of genuine multiparty classical correlations, even in macroscopic systems. Such possibilities can have important implications in the physics of quantum information and phase transitions.

Heat capacity as an indicator of entanglement

Physical Review B - Condensed Matter and Materials Physics 78:6 (2008)

Authors:

M Wieśniak, V Vedral, C Brukner

Abstract:

We demonstrate that the presence of entanglement in macroscopic bodies (e.g., solids) in thermodynamical equilibrium could be revealed by measuring heat capacity. The idea is that if the system was in a separable state, then for certain Hamiltonians heat capacity would not tend asymptotically to zero as the temperature approaches absolute zero. Since this would contradict the third law of thermodynamics, one concludes that the system must contain entanglement. The separable bounds are obtained by minimalization of the heat capacity over separable states and using its universal low-temperature behavior. Our results open up a possibility to use standard experimental techniques of solid-state physics-namely, heat-capacity measurements-to detect entanglement in macroscopic samples. © 2008 The American Physical Society.