Nonintegrability and the Fourier heat conduction law

Chen, Shunda; Wang, Jiao; Casati, Giulio; Benenti, Giuliano

doi:10.1103/physreve.90.032134

Cited by 60 publications

(83 citation statements)

References 26 publications

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“…(11), while for systems with AHT this has the scaling form in Eq. (12) and one again has super-diffusive growth of the MSD [21], now defined as…”

Section: Bmentioning

confidence: 99%

“…Several theoretical as well as large scale numerical studies have been performed on different mathematical model systems to understand the necessary and sufficient conditions needed in the microscopic description to validate Fourier's law at the macroscopic level [2][3][4]. Surprisingly, these studies suggest that Fourier's law is probably not valid in many one-dimensional systems and one finds that the thermal conductivity κ diverges with system size N as κ ∼ N α where 0 < α < 1 [2][3][4][5][6][7][8][9][10][11][12]. This is referred to as anomalous heat transport (AHT).…”

mentioning

confidence: 99%

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Anomalous Heat Transport in One Dimensional Systems: A Description Using Non-local Fractional-Type Diffusion Equation

Dhar

Kundu

2019

Front. Phys.

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It has been observed in many numerical simulations, experiments and from various theoretical treatments that heat transport in one-dimensional systems of interacting particles cannot be described by the phenomenological Fourier's law. The picture that has emerged from studies over the last few years is that Fourier's law gets replaced by a spatially non-local linear equation wherein the current at a point gets contributions from the temperature gradients in other parts of the system. Correspondingly the usual heat diffusion equation gets replaced by a non-local fractional-type diffusion equation. In this review, we describe the various theoretical approaches which lead to this framework and also discuss recent progress on this problem.

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“…(11), while for systems with AHT this has the scaling form in Eq. (12) and one again has super-diffusive growth of the MSD [21], now defined as…”

Section: Bmentioning

confidence: 99%

mentioning

confidence: 99%

Anomalous Heat Transport in One Dimensional Systems: A Description Using Non-local Fractional-Type Diffusion Equation

Dhar

Kundu

2019

Front. Phys.

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“…As a consequence, ZT exhibits a rapid, liner growth with the system size. While the Fourier-like regime might be an intermediate (in the system size) regime, followed by an asymptotic regime of anomalous thermal conductivity κ ∼ Λ 1/3 [83,52], the range of validity of such regime may expand rapidly as an integrable limit is approached [42]. We point out that it is a priori not excluded that there exist models where the long-time limit t → ∞ and the thermodynamical limit Λ → ∞ do not commute when computing the Drude weights.…”

Section: Conservation Laws and Thermoelectric Efficiencymentioning

confidence: 99%

“…This conclusion, however, might be not correct as shown in [42], where the heat conductivity of the one-dimensional diatomic hard-point gas model was studied. As shown in Fig.…”

mentioning

confidence: 94%

From Thermal Rectifiers to Thermoelectric Devices

Benenti

Casati

Mejía‐Monasterio

et al. 2016

Thermal Transport in Low Dimensions

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We discuss thermal rectification and thermoelectric energy conversion from the perspective of nonequilibrium statistical mechanics and dynamical systems theory. After preliminary considerations on the dynamical foundations of the phenomenological Fourier law in classical and quantum mechanics, we illustrate ways to control the phononic heat flow and design thermal diodes. Finally, we consider the coupled transport of heat and charge and discuss several general mechanisms for optimizing the figure of merit of thermoelectric efficiency.

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“…Similar features were observed in the trapped hard rod system [29], where it was observed that the system become chaotic after a characteristic time scale but fails to thermalize even at extremely large times. For momentum-conserving systems surprising features (e.g apparent diffusive transport) has been reported when a system is taken slightly out of integrability, for example arXiv:1812.11770v1 [cond-mat.stat-mech] 31 Dec 2018 in the Fermi-Pasta-Ulam chain at low temperatures [15 and 16] and the alternate mass hard particle gas, at a mass ratio close to one [12].…”

Section: Introductionmentioning

confidence: 99%

Transport Properties of the Classical Toda Chain: Effect of a Pinning Potential

et al. 2019

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We consider energy transport in the classical Toda chain in the presence of an additional pinning potential. The pinning potential is expected to destroy the integrability of the system and an interesting question is to see the signatures of this breaking of integrability on energy transport. We investigate this by a study of the non-equilibrium steady state of the system connected to heat baths as well as the study of equilibrium correlations. Typical signatures of integrable systems are a size-independent energy current, a flat bulk temperature profile and ballistic scaling of equilibrium dynamical correlations, these results being valid in the thermodynamic limit. We find that, as expected, these properties change drastically on introducing the pinning potential in the Toda model. In particular, we find that the effect of a harmonic pinning potential is drastically smaller at low temperatures, compared to a quartic pinning potential. We explain this by noting that at low temperatures the Toda potential can be approximated by a harmonic inter-particle potential for which the addition of harmonic pinning does not destroy integrability.

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Nonintegrability and the Fourier heat conduction law

Cited by 60 publications

References 26 publications

Anomalous Heat Transport in One Dimensional Systems: A Description Using Non-local Fractional-Type Diffusion Equation

Anomalous Heat Transport in One Dimensional Systems: A Description Using Non-local Fractional-Type Diffusion Equation

From Thermal Rectifiers to Thermoelectric Devices

Transport Properties of the Classical Toda Chain: Effect of a Pinning Potential

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