Cargando…

On the Definition of Energy Flux in One-Dimensional Chains of Particles

We review two well-known definitions present in the literature, which are used to define the heat or energy flux in one dimensional chains. One definition equates the energy variation per particle to a discretized flux difference, which we here show it also corresponds to the flux of energy in the z...

Descripción completa

Detalles Bibliográficos
Autor principal: De Gregorio, Paolo
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7514340/
http://dx.doi.org/10.3390/e21111036
_version_ 1783586565572788224
author De Gregorio, Paolo
author_facet De Gregorio, Paolo
author_sort De Gregorio, Paolo
collection PubMed
description We review two well-known definitions present in the literature, which are used to define the heat or energy flux in one dimensional chains. One definition equates the energy variation per particle to a discretized flux difference, which we here show it also corresponds to the flux of energy in the zero wavenumber limit in Fourier space, concurrently providing a general formula valid for all wavelengths. The other relies somewhat elaborately on a definition of the flux, which is a function of every coordinate in the line. We try to shed further light on their significance by introducing a novel integral operator, acting over movable boundaries represented by the neighboring particles’ positions, or some combinations thereof. By specializing to the case of chains with the particles’ order conserved, we show that the first definition corresponds to applying the differential continuity-equation operator after the application of the integral operator. Conversely, the second definition corresponds to applying the introduced integral operator to the energy flux. It is, therefore, an integral quantity and not a local quantity. More worryingly, it does not satisfy in any obvious way an equation of continuity. We show that in stationary states, the first definition is resilient to several formally legitimate modifications of the (models of) energy density distribution, while the second is not. On the other hand, it seems peculiar that this integral definition appears to capture a transport contribution, which may be called of convective nature, which is altogether missed by the former definition. In an attempt to connect the dots, we propose that the locally integrated flux divided by the inter-particle distance is a good measure of the energy flux. We show that the proposition can be explicitly constructed analytically by an ad hoc modification of the chosen model for the energy density.
format Online
Article
Text
id pubmed-7514340
institution National Center for Biotechnology Information
language English
publishDate 2019
publisher MDPI
record_format MEDLINE/PubMed
spelling pubmed-75143402020-11-09 On the Definition of Energy Flux in One-Dimensional Chains of Particles De Gregorio, Paolo Entropy (Basel) Article We review two well-known definitions present in the literature, which are used to define the heat or energy flux in one dimensional chains. One definition equates the energy variation per particle to a discretized flux difference, which we here show it also corresponds to the flux of energy in the zero wavenumber limit in Fourier space, concurrently providing a general formula valid for all wavelengths. The other relies somewhat elaborately on a definition of the flux, which is a function of every coordinate in the line. We try to shed further light on their significance by introducing a novel integral operator, acting over movable boundaries represented by the neighboring particles’ positions, or some combinations thereof. By specializing to the case of chains with the particles’ order conserved, we show that the first definition corresponds to applying the differential continuity-equation operator after the application of the integral operator. Conversely, the second definition corresponds to applying the introduced integral operator to the energy flux. It is, therefore, an integral quantity and not a local quantity. More worryingly, it does not satisfy in any obvious way an equation of continuity. We show that in stationary states, the first definition is resilient to several formally legitimate modifications of the (models of) energy density distribution, while the second is not. On the other hand, it seems peculiar that this integral definition appears to capture a transport contribution, which may be called of convective nature, which is altogether missed by the former definition. In an attempt to connect the dots, we propose that the locally integrated flux divided by the inter-particle distance is a good measure of the energy flux. We show that the proposition can be explicitly constructed analytically by an ad hoc modification of the chosen model for the energy density. MDPI 2019-10-25 /pmc/articles/PMC7514340/ http://dx.doi.org/10.3390/e21111036 Text en © 2019 by the author. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
De Gregorio, Paolo
On the Definition of Energy Flux in One-Dimensional Chains of Particles
title On the Definition of Energy Flux in One-Dimensional Chains of Particles
title_full On the Definition of Energy Flux in One-Dimensional Chains of Particles
title_fullStr On the Definition of Energy Flux in One-Dimensional Chains of Particles
title_full_unstemmed On the Definition of Energy Flux in One-Dimensional Chains of Particles
title_short On the Definition of Energy Flux in One-Dimensional Chains of Particles
title_sort on the definition of energy flux in one-dimensional chains of particles
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7514340/
http://dx.doi.org/10.3390/e21111036
work_keys_str_mv AT degregoriopaolo onthedefinitionofenergyfluxinonedimensionalchainsofparticles