Prof Vlatko Vedral FInstP

Quantum optics, molecular spectroscopy and low-temperature spectroscopy: general discussion

Chapter in , Royal Society of Chemistry (RSC) 184 (2015) 275-303

Authors:

Michel Orrit, Geraint Evans, Thorben Cordes, Irena Kratochvilova, William Moerner, Lisa-Maria Needham, Sergey Sekatskii, Yuri Vainer, Sanli Faez, Vlatko Vedral, Himangshu Prabal Goswami, Alex Clark, Alfred J Meixner, Lukasz Piatkowski, Victoria Birkedal, Vahid Sandoghdar, Gary M Skinner, Wolfgang Langbein, Jiangfeng Du, Felix Koberling, Jens Michaelis, Fazhan Shi, Robert Taylor, Arindam Chowdhury, Brahim Lounis, Niek van Hulst, Patrick El-Khoury, Lukas Novotny, Jörg Wrachtrup, Tristan Farrow, Andrei Naumov, Maxim Gladush, Ronald Hanson

Towards witnessing quantum effects in complex molecules

Faraday Discussions Royal Society of Chemistry (RSC) 184 (2015) 183-191

Authors:

T Farrow, RA Taylor, V Vedral

Replicating the benefits of closed timelike curves without breaking causality

(2014)

Authors:

Xiao Yuan, Syed M Assad, Jayne Thompson, Jing Yan Haw, Vlatko Vedral, Timothy C Ralph, Ping Koy Lam, Christian Weedbrook, Mile Gu

Discord as a quantum resource for bi-partite communication

AIP Conference Proceedings AIP Publishing 1633:1 (2014) 116-118

Authors:

Helen M Chrzanowski, Mile Gu, Syed M Assad, Thomas Symul, Kavan Modi, Timothy C Ralph, Vlatko Vedral, Ping Koy Lam

Maxwell's daemon: information versus particle statistics

Scientific Reports Springer Nature 4 (2014) 6995

Authors:

M Plesch, O Dahlsten, J Goold, Vlatko Vedral

Abstract:

Maxwell's daemon is a popular personification of a principle connecting information gain and extractable work in thermodynamics. A Szilard Engine is a particular hypothetical realization of Maxwell's daemon, which is able to extract work from a single thermal reservoir by measuring the position of particle(s) within the system. Here we investigate the role of particle statistics in the whole process; namely, how the extractable work changes if instead of classical particles fermions or bosons are used as the working medium. We give a unifying argument for the optimal work in the different cases: the extractable work is determined solely by the information gain of the initial measurement, as measured by the mutual information, regardless of the number and type of particles which constitute the working substance.