Fluctuation-dissipation theorem for nonequilibrium quantum systems

2016 ◽  
Vol 115 (2) ◽  
pp. 20004 ◽  
Author(s):  
Zhedong Zhang ◽  
Wei Wu ◽  
Jin Wang
Keyword(s):  
Quantum Systems ◽  
Fluctuation Dissipation ◽  
Fluctuation Dissipation Theorem

scholarly journals Fluctuation-dissipation theorem for non-equilibrium quantum systems

Quantum ◽  
2018 ◽  
Vol 2 ◽  
pp. 66 ◽  
Author(s):  
Mohammad Mehboudi ◽  
Anna Sanpera ◽  
Juan M. R. Parrondo
Keyword(s):  
Statistical Physics ◽  
Logarithmic Derivative ◽  
Quantum Systems ◽  
Quantum Metrology ◽  
Fluctuation Dissipation ◽  
Fluctuation Dissipation Theorem ◽  
Time Correlations ◽  
Central Result ◽  
Arbitrary Quantum ◽  
Non Equilibrium

The fluctuation-dissipation theorem (FDT) is a central result in statistical physics, both for classical and quantum systems. It establishes a relationship between the linear response of a system under a time-dependent perturbation and time correlations of certain observables in equilibrium. Here we derive a generalization of the theorem which can be applied to any Markov quantum system and makes use of the symmetric logarithmic derivative (SLD). There are several important benefits from our approach. First, such a formulation clarifies the relation between classical and quantum versions of the equilibrium FDT. Second, and more important, it facilitates the extension of the FDT to arbitrary quantum Markovian evolution, as given by quantum maps. Third, it clarifies the connection between the FDT and quantum metrology in systems with a non-equilibrium steady state.

scholarly journals Fluctuation-dissipation theorem in isolated quantum systems out of equilibrium

2014 ◽  
Vol 510 ◽  
pp. 012035
Author(s):  
Ehsan Khatami ◽  
Guido Pupillo ◽  
Mark Srednicki ◽  
Marcos Rigol
Keyword(s):  
Quantum Systems ◽  
Fluctuation Dissipation ◽  
Fluctuation Dissipation Theorem

scholarly journals Ergodicity probes: using time-fluctuations to measure the Hilbert space dimension

Quantum ◽  
2019 ◽  
Vol 3 ◽  
pp. 207
Author(s):  
Charlie Nation ◽  
Diego Porras
Keyword(s):  
Hilbert Space ◽  
Space Dimension ◽  
Quantum Systems ◽  
Quantum States ◽  
Quantum Computers ◽  
Quantum Devices ◽  
Fluctuation Dissipation ◽  
Fluctuation Dissipation Theorem ◽  
Quantum Device ◽  
Meaningful Measure

Quantum devices, such as quantum simulators, quantum annealers, and quantum computers, may be exploited to solve problems beyond what is tractable with classical computers. This may be achieved as the Hilbert space available to perform such `calculations' is far larger than that which may be classically simulated. In practice, however, quantum devices have imperfections, which may limit the accessibility to the whole Hilbert space. We thus determine that the dimension of the space of quantum states that are available to a quantum device is a meaningful measure of its functionality, though unfortunately this quantity cannot be directly experimentally determined. Here we outline an experimentally realisable approach to obtaining the required Hilbert space dimension of such a device to compute its time evolution, by exploiting the thermalization dynamics of a probe qubit. This is achieved by obtaining a fluctuation-dissipation theorem for high-temperature chaotic quantum systems, which facilitates the extraction of information on the Hilbert space dimension via measurements of the decay rate, and time-fluctuations.

scholarly journals The Response to Stratospheric Forcing and Its Dependence on the State of the Troposphere

2009 ◽  
Vol 66 (7) ◽  
pp. 2107-2115 ◽  
Author(s):  
Cegeon J. Chan ◽  
R. Alan Plumb
Keyword(s):  
Time Scale ◽  
Equilibrium Temperature ◽  
Intrinsic Variability ◽  
Winter Solstice ◽  
Fluctuation Dissipation ◽  
Fluctuation Dissipation Theorem ◽  
Order Of Magnitude ◽  
Leading Mode ◽  
Set Up ◽  
Hemisphere Winter

Abstract In simple GCMs, the time scale associated with the persistence of one particular phase of the model’s leading mode of variability can often be unrealistically large. In a particularly extreme example, the time scale in the Polvani–Kushner model is about an order of magnitude larger than the observed atmosphere. From the fluctuation–dissipation theorem, one implication of these simple models is that responses are exaggerated, since such setups are overly sensitive to any external forcing. Although the model’s equilibrium temperature is set up to represent perpetual Southern Hemisphere winter solstice, it is found that the tropospheric eddy-driven jet has a preference for two distinct regions: the subtropics and midlatitudes. Because of this bimodality, the jet persists in one region for thousands of days before “switching” to another. As a result, the time scale associated with the intrinsic variability is unrealistic. In this paper, the authors systematically vary the model’s tropospheric equilibrium temperature profile, one configuration being identical to that of Polvani and Kushner. Modest changes to the tropospheric state to either side of the parameter space removed the bimodality in the zonal-mean zonal jet’s spatial distribution and significantly reduced the time scale associated with the model’s internal mode. Consequently, the tropospheric response to the same stratospheric forcing is significantly weaker than in the Polvani and Kushner case.

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