Frontiers of quantum physics

Nonlocality of a single particle.

Phys Rev Lett 99:18 (2007) 180404

Authors:

Jacob Dunningham, Vlatko Vedral

Abstract:

There has been a great deal of debate surrounding the issue of whether it is possible for a single photon to exhibit nonlocality. A number of schemes have been proposed that claim to demonstrate this effect, but each has been met with significant opposition. The objections hinge largely on the fact that these schemes use unobservable initial states and so, it is claimed, they do not represent experiments that could actually be performed. Here we show how it is possible to overcome these objections by presenting an experimentally feasible scheme that uses realistic initial states. Furthermore, all the techniques required for photons are equally applicable to atoms. It should, therefore, also be possible to use this scheme to verify the nonlocality of a single massive particle.

Dimensionality-induced entanglement in macroscopic dimer systems

Physical Review A - Atomic, Molecular, and Optical Physics 76:5 (2007)

Authors:

D Kaszlikowski, W Son, V Vedral

Abstract:

We investigate entanglement properties of mixtures of short-range spin- s dimer coverings in lattices of arbitrary topology and dimension. We show that in one spatial dimension nearest neighbor entanglement exists for any spin s. Surprisingly, in higher spatial dimensions there is a threshold value of spin s below which the nearest neighbor entanglement disappears. The traditional "classical" limit of large spin value corresponds to the highest nearest neighbor entanglement that we quantify using the negativity. © 2007 The American Physical Society.

Experimental Demonstration of the Unified Framework for the Mixed State Geometric Phase

(2007)

Authors:

Jiangfeng Du, Mingjun Shi, Jing Zhu, Vlatko Vedral, Xinhua Peng, Dieter Suter

Regional versus global entanglement in resonating-valence-bond states.

Phys Rev Lett 99:17 (2007) 170502

Authors:

Anushya Chandran, Dagomir Kaszlikowski, Aditi Sen De, Ujjwal Sen, Vlatko Vedral

Abstract:

We investigate the entanglement properties of resonating-valence-bond states on two and higher dimensional lattices, which play a significant role in our understanding of various many-body systems. We show that these states are genuinely multipartite entangled, while there is only a negligible amount of two-site entanglement. We comment on possible physical implications of our findings.

Nonadiabatic geometric quantum computation

Physical Review A - Atomic, Molecular, and Optical Physics 76:4 (2007)

Authors:

ZS Wang, C Wu, XL Feng, LC Kwek, CH Lai, CH Oh, V Vedral

Abstract:

A different way to realize nonadiabatic geometric quantum computation is proposed by varying parameters in the Hamiltonian for nuclear-magnetic resonance, where the dynamical and geometric phases are implemented separately without the usual operational process. Therefore the phase accumulated in the geometric gate is a pure geometric phase for any input state. In comparison with the conventional geometric gates by rotating operations, our approach simplifies experimental implementations making them robust to certain experimental errors. In contrast to the unconventional geometric gates, our approach distinguishes the total and geometric phases and offers a wide choice of the relations between the dynamical and geometric phases. © 2007 The American Physical Society.