Thermal conductivity in harmonic lattices with random collisions

A. Casher; A. Dhar; A. Dhar; A. Dhar; A. Kundu; A. Mellet; A. Zola; C. Bernardin; C. Bernardin; C. Bernardin; C. Bernardin; C. Bernardin; C. Bernardin; Cédric Bernardin; D.M. Basko; D.W. Stroock; F. Huveneers; G. Basile; G. Basile; G. Basile; G. Basile; G. Basile; G. Basile; H. Spohn; H. Spohn; H. Spohn; H. Spohn; J. Fritz; J. Lukkarinen; L. Caffarelli; M. Jara; M. Jara; N. Even; O. Ajanki; R.E. Peierls; R.J. Rubin; S. Lepri; S. Lepri; S. Lepri; S. Olla; T. Verheggen; Tomasz Komorowski; V. Oganesyan; Y. Xu; Z. Rieder

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Thermal conductivity in harmonic lattices with random collisions

Abstract

We review recent rigorous mathematical results about the macroscopic behaviour of harmonic chains with the dynamics perturbed by a random exchange of velocities between nearest neighbor particles. The random exchange models the effects of nonlinearities of anharmonic chains and the resulting dynamics have similar macroscopic behaviour. In particular there is a superdiffusion of energy for unpinned acoustic chains. The corresponding evolution of the temperature profile is governed by a fractional heat equation. In non-acoustic chains we have normal diffusivity, even if momentum is conserved.Comment: Review paper, to appear in the Springer Lecture Notes in Physics volume "Thermal transport in low dimensions: from statistical physics to nanoscale heat transfer" (S. Lepri ed.