Prof Vlatko Vedral FInstP

Quantum macroscopicity versus distillation of macroscopic superpositions

(2014)

Authors:

Benjamin Yadin, Vlatko Vedral

Scale-estimation of quantum coherent energy transport in multiple-minima systems.

Scientific reports Nature Publishing Group 4 (2014) 5520

Authors:

T Farrow, Vlatko Vedral

Abstract:

A generic and intuitive model for coherent energy transport in multiple minima systems coupled to a quantum mechanical bath is shown. Using a simple spin-boson system, we illustrate how a generic donor-acceptor system can be brought into resonance using a narrow band of vibrational modes, such that the transfer efficiency of an electron-hole pair (exciton) is made arbitrarily high. Coherent transport phenomena in nature are of renewed interest since the discovery that a photon captured by the light-harvesting complex (LHC) in photosynthetic organisms can be conveyed to a chemical reaction centre with near-perfect efficiency. Classical explanations of the transfer use stochastic diffusion to model the hopping motion of a photo-excited exciton. This accounts inadequately for the speed and efficiency of the energy transfer measured in a series of recent landmark experiments. Taking a quantum mechanical perspective can help capture the salient features of the efficient part of that transfer. To show the versatility of the model, we extend it to a multiple minima system comprising seven-sites, reminiscent of the widely studied Fenna-Matthews-Olson (FMO) light-harvesting complex. We show that an idealised transport model for multiple minima coupled to a narrow-band phonon can transport energy with arbitrarily high efficiency.

Scale-estimation of quantum coherent energy transport in multiple-minima systems

(2014)

Authors:

Tristan Farrow, Vlatko Vedral

Classification of macroscopic quantum effects

(2014)

Authors:

Tristan Farrow, Vlatko Vedral

Work and quantum phase transitions: quantum latency.

Physical review. E, Statistical, nonlinear, and soft matter physics 89:6 (2014) 062103

Authors:

E Mascarenhas, H Bragança, R Dorner, M França Santos, V Vedral, K Modi, J Goold

Abstract:

We study the physics of quantum phase transitions from the perspective of nonequilibrium thermodynamics. For first-order quantum phase transitions, we find that the average work done per quench in crossing the critical point is discontinuous. This leads us to introduce the quantum latent work in analogy with the classical latent heat of first order classical phase transitions. For second order quantum phase transitions the irreversible work is closely related to the fidelity susceptibility for weak sudden quenches of the system Hamiltonian. We demonstrate our ideas with numerical simulations of first, second, and infinite order phase transitions in various spin chain models.