Your search keyword '"Goold, John"' showing total 7 results

1. Experimental reconstruction of work distribution and study of fluctuation relations in a closed quantum system.

Author

Batalhão TB, Souza AM, Mazzola L, Auccaise R, Sarthour RS, Oliveira IS, Goold J, De Chiara G, Paternostro M, and Serra RM

Subjects

Chloroform chemistry, Fourier Analysis, Kinetics, Magnetic Resonance Spectroscopy, Thermodynamics, Models, Theoretical, Quantum Theory

Abstract

We report the experimental reconstruction of the nonequilibrium work probability distribution in a closed quantum system, and the study of the corresponding quantum fluctuation relations. The experiment uses a liquid-state nuclear magnetic resonance platform that offers full control on the preparation and dynamics of the system. Our endeavors enable the characterization of the out-of-equilibrium dynamics of a quantum spin from a finite-time thermodynamics viewpoint.

Published

2014

2. Measuring the heat exchange of a quantum process.

Author

Goold J, Poschinger U, and Modi K

Subjects

Quantum Theory, Thermodynamics

Abstract

Very recently, interferometric methods have been proposed to measure the full statistics of work performed on a driven quantum system [Dorner et al., Phys. Rev. Lett. 110, 230601 (2013) and Mazzola et al., Phys. Rev. Lett. 110, 230602 (2013)]. The advantage of such schemes is that they replace the necessity to make projective measurements by performing phase estimation on an appropriately coupled ancilla qubit. These proposals are one possible route to the tangible experimental exploration of quantum thermodynamics, a subject which is the center of much current attention due to the current control of mesoscopic quantum systems. In this Rapid Communication we demonstrate that a modification of the phase estimation protocols can be used in order to measure the heat distribution of a quantum process. In addition, we demonstrate how our scheme maybe implemented using ion trap technology. Our scheme should pave the way for experimental explorations of the Landauer principle and hence the intricate energy to information conversion in mesoscopic quantum systems.

Published

2014

3. Evidence of Kardar-Parisi-Zhang scaling on a digital quantum simulator.

Author

Keenan, Nathan, Robertson, Niall F., Murphy, Tara, Zhuk, Sergiy, and Goold, John

Subjects

NONEQUILIBRIUM statistical mechanics, QUANTUM theory, NUCLEAR spin, DIGITAL computer simulation, SCHRODINGER equation, SPIN excitations

Abstract

Understanding how hydrodynamic behaviour emerges from the unitary evolution of the many-particle Schrödinger equation is a central goal of non-equilibrium statistical mechanics. In this work we implement a digital simulation of the discrete time quantum dynamics of a spin- 1 2 XXZ spin chain on a noisy near-term quantum device, and we extract the high temperature transport exponent at the isotropic point. We simulate the temporal decay of the relevant spin correlation function at high temperature using a pseudo-random state generated by a random circuit that is specifically tailored to the ibmq-montreal 27 qubit device. The resulting output is a spin excitation on a homogeneous background on a 21 qubit chain on the device. From the subsequent discrete time dynamics on the device we are able to extract an anomalous super-diffusive exponent consistent with the conjectured Kardar-Parisi-Zhang (KPZ) scaling at the isotropic point. Furthermore we simulate the restoration of spin diffusion with the application of an integrability breaking potential. [ABSTRACT FROM AUTHOR]

Published

2023

4. Analysis of the conditional mutual information in ballistic and diffusive non-equilibrium steady-states.

Author

Malouf, William T B, Goold, John, Adesso, Gerardo, and Landi, Gabriel T

Subjects

*BALLISTIC conduction, *MARKOV processes, *QUANTUM theory

Abstract

The conditional mutual information (CMI) quantifies the amount of correlations shared between A and CgivenB. It therefore functions as a more general quantifier of bipartite correlations in multipartite scenarios, playing an important role in the theory of quantum Markov chains. In this paper we carry out a detailed study on the behavior of the CMI in non-equilibrium steady-states (NESS) of a quantum chain placed between two baths at different temperatures. These results are used to shed light on the mechanisms behind ballistic and diffusive transport regimes and how they affect correlations between different parts of a chain. We carry our study for the specific case of a 1D bosonic chain subject to local Lindblad dissipators at the boundaries. In addition, the chain is also subject to self-consistent reservoirs at each site, which are used to tune the transport between ballistic and diffusive. As a result, we find that the CMI is independent of the chain size L in the ballistic regime, but decays algebraically with L in the diffusive case. Finally, we also show how this scaling can be used to discuss the notion of local thermalization in non-equilibrium steady-states. [ABSTRACT FROM AUTHOR]

Published

2020

5. Nonequilibrium Quantum Landauer Principle.

Author

Goold, John, Patemostro, Mauro, and Modi, Kavan

Subjects

*NONEQUILIBRIUM thermodynamics, *QUANTUM correlations, *PHASE transitions, *PHOTONS, *THERMODYNAMICS, *QUANTUM theory

Abstract

Using the operational framework of completely positive, trace preserving operations and thermodynamic fluctuation relations, we derive a lower bound for the heat exchange in a Landauer erasure process on a quantum system. Our bound comes from a nonphenomenological derivation of the Landauer principle which holds for generic nonequilibrium dynamics. Furthermore, the bound depends on the nonunitality of dynamics, giving it a physical significance that differs from other derivations. We apply our framework to the model of a spin-1/2 system coupled to an interacting spin chain at finite temperature. [ABSTRACT FROM AUTHOR]

Published

2015

6. Effects of quantum coherence in metalloprotein electron transfer.

Author

Dorner, Ross, Goold, John, Heaney, Libby, Farrow, Tristan, and Vedral, Vlatko

Subjects

*QUANTUM theory, *COHERENCE (Physics), *METALLOPROTEINS, *INTRAMOLECULAR charge transfer, *PARAMETER estimation, *POTENTIAL theory (Physics)

Abstract

Many intramolecular electron transfer (ET) reactions in biology are mediated by metal centers in proteins. This process is commonly described by a model of diffusive hopping according to the semiclassical theories of Marcus and Hopfield. However, recent studies have raised the possibility that nontrivial quantum mechanical effects play a functioning role in certain biomolecular processes. Here, we investigate the potential effects of quantum coherence in biological ET by extending the semiclassical model to allow for the possibility of quantum coherent phenomena using a quantum master equation based on the Holstein Hamiltonian. We test the model on the structurally defined chain of seven iron-sulfur clusters in nicotinamide adenine dinucleotide plus hydrogen:ubiquinone oxidoreductase (complex I), a crucial respiratory enzyme and one of the longest chains of metal centers in biology. Using experimental parameters where possible, we find that, in limited circumstances, a small quantum mechanical contribution can provide a marked increase in the ET rate above the semiclassical diffusive-hopping rate. Under typical biological conditions, our model reduces to well-known diffusive behavior. [ABSTRACT FROM AUTHOR]

Published

2012

7. In Situ Thermometry of a Cold Fermi Gas via Dephasing Impurities.

Author

Mitchison, Mark T., Fogarty, Thomás, Guarnieri, Giacomo, Campbell, Steve, Busch, Thomas, and Goold, John

Subjects

*COLD gases, *THERMOMETRY, *ELECTRON gas, *GAS dynamics, *PARAMETER estimation, *QUANTUM theory

Abstract

The precise measurement of low temperatures is a challenging, important, and fundamental task for quantum science. In particular, in situ thermometry is highly desirable for cold atomic systems due to their potential for quantum simulation. Here, we demonstrate that the temperature of a noninteracting Fermi gas can be accurately inferred from the nonequilibrium dynamics of impurities immersed within it, using an interferometric protocol and established experimental methods. Adopting tools from the theory of quantum parameter estimation, we show that our proposed scheme achieves optimal precision in the relevant temperature regime for degenerate Fermi gases in current experiments. We also discover an intriguing trade-off between measurement time and thermometric precision that is controlled by the impurity-gas coupling, with weak coupling leading to the greatest sensitivities. This is explained as a consequence of the slow decoherence associated with the onset of the Anderson orthogonality catastrophe, which dominates the gas dynamics following its local interaction with the immersed impurity. [ABSTRACT FROM AUTHOR]

Published

2020