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Title: Extending the range of validity of Fourier's law into the kinetic transport regime via asymptotic solution of the phonon Boltzmann transport equation

Abstract

We derive the continuum equations and boundary conditions governing phonon-mediated heat transfer in the limit of a small but finite mean-free path from the asymptotic solution of the linearized Boltzmann equation in the relaxation time approximation. Our method uses the ratio of the mean-free path to the characteristic system length scale, also known as the Knudsen number, as the expansion parameter to study the effects of boundaries on the breakdown of the Fourier description. We show that, in the bulk, the traditional heat conduction equation using Fourier's law as a constitutive relation is valid at least up to second order in the Knudsen number for steady problems and first order for time-dependent problems. Yet, this description does not hold within distances on the order of a few mean-free paths from the boundary; this breakdown is a result of kinetic effects that are always present in the boundary vicinity and require solution of a Boltzmann boundary layer problem to be determined. Matching the inner, boundary layer solution to the outer, bulk solution yields boundary conditions for the Fourier description as well as additive corrections in the form of universal kinetic boundary layers; both are found to be proportional to the bulk-solutionmore » gradients at the boundary and parametrized by the material model and the phonon-boundary interaction model (Boltzmann boundary condition). Our derivation shows that the traditional no-jump boundary condition for prescribed temperature boundaries and the no-flux boundary condition for diffusely reflecting boundaries are appropriate only to zeroth order in the Knudsen number; at higher order, boundary conditions are of the jump type. We illustrate the utility of the asymptotic solution procedure by demonstrating that it can be used to predict the Kapitza resistance (and temperature jump) associated with an interface between two materials. All results are validated via comparisons with low-variance deviational Monte Carlo simulations.« less

Authors:
 [1];  [1]
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  1. Massachusetts Inst. of Technology (MIT), Cambridge, MA (United States)
Publication Date:
Research Org.:
Massachusetts Inst. of Technology (MIT), Cambridge, MA (United States); Energy Frontier Research Centers (EFRC) (United States). Solid-State Solar-Thermal Energy Conversion Center (S3TEC)
Sponsoring Org.:
USDOE Office of Science (SC), Basic Energy Sciences (BES)
OSTI Identifier:
1371448
Alternate Identifier(s):
OSTI ID: 1235954
Grant/Contract Number:  
SC0001299; FG02-09ER46577
Resource Type:
Accepted Manuscript
Journal Name:
Physical Review B
Additional Journal Information:
Journal Volume: 93; Journal Issue: 4; Related Information: S3TEC partners with Massachusetts Institute of Technology (lead); Boston College; Oak Ridge National Laboratory; Rensselaer Polytechnic Institute; Journal ID: ISSN 2469-9950
Publisher:
American Physical Society (APS)
Country of Publication:
United States
Language:
English
Subject:
75 CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY; solar (photovoltaic); solar (thermal); solid state lighting; phonons; thermal conductivity; thermoelectric; defects; mechanical behavior; charge transport; spin dynamics; materials and chemistry by design; optics; synthesis (novel materials); synthesis (self-assembly); synthesis (scalable processing)

Citation Formats

Péraud, Jean-Philippe M., and Hadjiconstantinou, Nicolas G. Extending the range of validity of Fourier's law into the kinetic transport regime via asymptotic solution of the phonon Boltzmann transport equation. United States: N. p., 2016. Web. doi:10.1103/PhysRevB.93.045424.
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Péraud, Jean-Philippe M., & Hadjiconstantinou, Nicolas G. Extending the range of validity of Fourier's law into the kinetic transport regime via asymptotic solution of the phonon Boltzmann transport equation. United States. https://doi.org/10.1103/PhysRevB.93.045424
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Péraud, Jean-Philippe M., and Hadjiconstantinou, Nicolas G. Mon . "Extending the range of validity of Fourier's law into the kinetic transport regime via asymptotic solution of the phonon Boltzmann transport equation". United States. https://doi.org/10.1103/PhysRevB.93.045424. https://www.osti.gov/servlets/purl/1371448.
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@article{osti_1371448,
title = {Extending the range of validity of Fourier's law into the kinetic transport regime via asymptotic solution of the phonon Boltzmann transport equation},
author = {Péraud, Jean-Philippe M. and Hadjiconstantinou, Nicolas G.},
abstractNote = {We derive the continuum equations and boundary conditions governing phonon-mediated heat transfer in the limit of a small but finite mean-free path from the asymptotic solution of the linearized Boltzmann equation in the relaxation time approximation. Our method uses the ratio of the mean-free path to the characteristic system length scale, also known as the Knudsen number, as the expansion parameter to study the effects of boundaries on the breakdown of the Fourier description. We show that, in the bulk, the traditional heat conduction equation using Fourier's law as a constitutive relation is valid at least up to second order in the Knudsen number for steady problems and first order for time-dependent problems. Yet, this description does not hold within distances on the order of a few mean-free paths from the boundary; this breakdown is a result of kinetic effects that are always present in the boundary vicinity and require solution of a Boltzmann boundary layer problem to be determined. Matching the inner, boundary layer solution to the outer, bulk solution yields boundary conditions for the Fourier description as well as additive corrections in the form of universal kinetic boundary layers; both are found to be proportional to the bulk-solution gradients at the boundary and parametrized by the material model and the phonon-boundary interaction model (Boltzmann boundary condition). Our derivation shows that the traditional no-jump boundary condition for prescribed temperature boundaries and the no-flux boundary condition for diffusely reflecting boundaries are appropriate only to zeroth order in the Knudsen number; at higher order, boundary conditions are of the jump type. We illustrate the utility of the asymptotic solution procedure by demonstrating that it can be used to predict the Kapitza resistance (and temperature jump) associated with an interface between two materials. All results are validated via comparisons with low-variance deviational Monte Carlo simulations.},
doi = {10.1103/PhysRevB.93.045424},
journal = {Physical Review B},
number = 4,
volume = 93,
place = {United States},
year = {Mon Jan 25 00:00:00 EST 2016},
month = {Mon Jan 25 00:00:00 EST 2016}
}
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https://doi.org/10.1103/PhysRevB.93.045424
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Cited by: 23 works
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Figures / Tables:

FIG. 1 FIG. 1: Temperature profile associated with $τ$K1,1 = TK1,1/ (∂TG0/∂x1)|η=0, for three relaxation time models. The x axis is scaled by the maximum free path $Λ$max of each model.
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    Works referencing / citing this record:

    Thermal transport at the nanoscale: A Fourier's law vs. phonon Boltzmann equation study
    journal, January 2017

    • Kaiser, J.; Feng, T.; Maassen, J.
    • Journal of Applied Physics, Vol. 121, Issue 4
    • DOI: 10.1063/1.4974872

    Ab initio based investigation of thermal transport in superlattices using the Boltzmann equation: Assessing the role of phonon coherence
    journal, February 2019

    • Ye, Erika; Minnich, Austin J.
    • Journal of Applied Physics, Vol. 125, Issue 5
    • DOI: 10.1063/1.5075481

    Slip Boundary Conditions in Ballistic–Diffusive Heat Transport in Nanostructures
    journal, July 2017

    Nonequilibrium phonon transport across nanoscale interfaces
    journal, September 2019

    Universal molecular-kinetic scaling relation for slip of a simple fluid at a solid boundary
    journal, June 2019

    Interfacial Phonon Transport Through Si/Ge Multilayer Film Using Monte Carlo Scheme With Spectral Transmissivity
    journal, May 2018

    Thermal Transport at the Nanoscale - A Fourier's Law vs. Phonon Boltzmann Equation Study
    text, January 2016

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      FIG. 6 (p. 14)figure
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      FIG. 8 (p. 17)figure
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