Prof Vlatko Vedral FInstP

Quantum thermodynamics for a model of an expanding Universe

Classical and Quantum Gravity IOP Publishing 33:3 (2016) 035003

Authors:

Nana Liu, John Goold, Ivette Fuentes, Vlatko Vedral, Kavan Modi, David Edward Bruschi

Entanglement Rényi α entropy

Physical Review A American Physical Society (APS) 93:2 (2016) 022324

Authors:

Yu-Xin Wang, Liang-Zhu Mu, Vlatko Vedral, Heng Fan

General framework for quantum macroscopicity in terms of coherence

Physical Review A American Physical Society (APS) 93:2 (2016) 022122

Authors:

Benjamin Yadin, Vlatko Vedral

Photonic Maxwell's Demon.

Physical review letters 116:5 (2016) 050401

Authors:

Mihai D Vidrighin, Oscar Dahlsten, Marco Barbieri, MS Kim, Vlatko Vedral, Ian A Walmsley

Abstract:

We report an experimental realization of Maxwell's demon in a photonic setup. We show that a measurement at the few-photons level followed by a feed-forward operation allows the extraction of work from intense thermal light into an electric circuit. The interpretation of the experiment stimulates the derivation of an equality relating work extraction to information acquired by measurement. We derive a bound using this relation and show that it is in agreement with the experimental results. Our work puts forward photonic systems as a platform for experiments related to information in thermodynamics.

Quantum Quasi-Zeno Dynamics: Transitions mediated by frequent projective measurements near the Zeno regime

arXiv ArXiv (2016)

Authors:

Thomas Elliott, Vlatko Vedral

Abstract:

Frequent observation of a quantum system leads to quantum Zeno physics, where the system evolution is constrained to states commensurate with the measurement outcome. We show that, more generally, the system can evolve between such states through higher-order virtual processes that pass through states outside the measurement subspace. We derive effective Hamiltonians to describe this evolution, and the dependence on the time between measurements. We demonstrate application of this phenomena to prototypical quantum many-body system examples, spin chains and atoms in optical lattices, where it facilitates correlated dynamical effects.