Real-time nonequilibrium dynamics of quantum glassy systems

Cugliandolo, Leticia F.; Lozano, Gustavo

doi:10.1103/physrevb.59.915

Cited by 81 publications

(130 citation statements)

References 124 publications

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“…In this paper a motivating question is whether the introduction of quantum fluctuations in a classical system out of equilibrium results in qualitatively new behavior at long time-scales. To date, the introduction of quantum fluctuations in theoretical glassy models has not led to qualitative changes, e.g., new slow quantum modes, in their long-time dynamics [1,2,3,4,5]. Quantum fluctuations often drive the glass transition to be first-order [6,7,8,9,10], and thus only qualitatively affect the dynamical behavior on short-time scales.…”

Section: Introductionmentioning

confidence: 99%

Dynamical study of the disordered quantump=2spherical model

Rokni¹,

Chandra²

2004

Phys. Rev. B

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We present a dynamical study of the disordered quantum p = 2 spherical model at long times. Its phase behavior as a function of spin-bath coupling, strength of quantum fluctuations and temperature is characterized, and we identify different paramagnetic and coarsened regions. A quantum critical point at zero temperature in the limit of vanishing dissipation is also found. Furthermore we show analytically that the fluctuation-dissipation theorem is obeyed in the stationary regime.

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Section: Introductionmentioning

confidence: 99%

Dynamical study of the disordered quantump=2spherical model

Rokni¹,

Chandra²

2004

Phys. Rev. B

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“…11. The relations between integrated responses and correlation functions in other quantum problems that also approach classical-like form in the aging regime were shown in [31,37].…”

Section: Linear Responsementioning

confidence: 99%

“…Finally, as a consequence of its disordered interactions, the system of rotors experiences intrinsic difficulties to reach equilibrium. Indeed, even if it were embedded within an equilibrium environment it would show a glassy phase [29,31] in some parts of the phase diagram.…”

Section: Quench Setupmentioning

confidence: 99%

“…This property allows us to write dynamic equations by averaging over disorder the generating functional itself hence without resorting to the use of replicas [31]. As in other quantum systems with quenched disorder [29,31,35,37], we are therefore interested in…”

Section: Average Over Disordermentioning

confidence: 99%

“…Moreover the connection with the Martin-Siggia-Rose generating functional in the classical limit is more straightforward in this representation [26,31]. One introduces new fields as 31) and the inversion relation…”

Section: Keldysh Rotationmentioning

confidence: 99%

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Coarsening of disordered quantum rotors under a bias voltage

2010

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We solve the dynamics of an ensemble of interacting rotors coupled to two leads at different chemical potential letting a current flow through the system and driving it out of equilibrium. We show that at low temperature the coarsening phase persists under the voltage drop up to a critical value of the applied potential that depends on the characteristics of the electron reservoirs. We discuss the properties of the critical surface in the temperature, voltage, strength of quantum fluctuations, and coupling to the bath phase diagram. We analyze the coarsening regime finding, in particular, which features are essentially quantum mechanical and which are basically classical in nature. We demonstrate that the system evolves via the growth of a coherence length with the same time dependence as in the classical limit, R(t) ≃ t 1/2 -the scalar curvature driven universality class. We obtain the scaling function of the correlation function at late epochs in the coarsening regime and we prove that it coincides with the classical one once a prefactor that encodes the dependence on all the parameters is factorized. We derive a generic formula for the current flowing through the system and we show that, for this model, it rapidly approaches a constant that we compute.

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Spectral form factor of a quantum spin glass

Winer

Barney

Baldwin

et al. 2022

J. High Energ. Phys.

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It is widely expected that systems which fully thermalize are chaotic in the sense of exhibiting random-matrix statistics of their energy level spacings, whereas integrable systems exhibit Poissonian statistics. In this paper, we investigate a third class: spin glasses. These systems are partially chaotic but do not achieve full thermalization due to large free energy barriers. We examine the level spacing statistics of a canonical infinite-range quantum spin glass, the quantum p-spherical model, using an analytic path integral approach. We find statistics consistent with a direct sum of independent random matrices, and show that the number of such matrices is equal to the number of distinct metastable configurations — the exponential of the spin glass “complexity” as obtained from the quantum Thouless-Anderson-Palmer equations. We also consider the statistical properties of the complexity itself and identify a set of contributions to the path integral which suggest a Poissonian distribution for the number of metastable configurations. Our results show that level spacing statistics can probe the ergodicity-breaking in quantum spin glasses and provide a way to generalize the notion of spin glass complexity beyond models with a semi-classical limit.

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Real-time nonequilibrium dynamics of quantum glassy systems

Cited by 81 publications

References 124 publications

Dynamical study of the disordered quantump=2spherical model

Dynamical study of the disordered quantump=2spherical model

Coarsening of disordered quantum rotors under a bias voltage

Spectral form factor of a quantum spin glass

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