Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles

We consider free lattice fermions subjected to a static bounded potential and a time- and space-dependent electric field. For any bounded convex region ℛ ⊂ ℝd (d ≥ 1) of space, electric fields E within R drive currents. At leading order, uniformly with respect to the volume R of R and the particular...

Full description

Saved in:
Bibliographic Details
Published in:Journal of mathematical physics 2015-05, Vol.56 (5), p.1
Main Authors: Bru, J.-B., de Siqueira Pedra, W., Hertling, C.
Format: Article
Language:English
Subjects:
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Conductivity
Correlation analysis
CORRELATION FUNCTIONS
ELECTRIC FIELDS
Electrical resistivity
FERMIONS
Fourier law
FOURIER TRANSFORMATION
Fourier transforms
HEAT PRODUCTION
Hilbert transformation
Operators (mathematics)
Parameters
Physics
Quadratic forms
SPACE DEPENDENCE
Time correlation functions
Time dependence
Variation
Viscosity
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
cited_by cdi_FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243
cites cdi_FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243
container_end_page
container_issue 5
container_start_page 1
container_title Journal of mathematical physics
container_volume 56
creator Bru, J.-B.
de Siqueira Pedra, W.
Hertling, C.
description We consider free lattice fermions subjected to a static bounded potential and a time- and space-dependent electric field. For any bounded convex region ℛ ⊂ ℝd (d ≥ 1) of space, electric fields E within R drive currents. At leading order, uniformly with respect to the volume R of R and the particular choice of the static potential, the dependency on E of the current is linear and described by a conductivity (tempered, operator-valued) distribution. Because of the positivity of the heat production, the real part of its Fourier transform is a positive measure, named here (microscopic) conductivity measure of R, in accordance with Ohm’s law in Fourier space. This finite measure is the Fourier transform of a time-correlation function of current fluctuations, i.e., the conductivity distribution satisfies Green–Kubo relations. We additionally show that this measure can also be seen as the boundary value of the Laplace–Fourier transform of a so-called quantum current viscosity. The real and imaginary parts of conductivity distributions are related to each other via the Hilbert transform, i.e., they satisfy Kramers–Kronig relations. At leading order, uniformly with respect to parameters, the heat production is the classical work performed by electric fields on the system in presence of currents. The conductivity measure is uniformly bounded with respect to parameters of the system and it is never the trivial measure 0 dν. Therefore, electric fields generally produce heat in such systems. In fact, the conductivity measure defines a quadratic form in the space of Schwartz functions, the Legendre–Fenchel transform of which describes the resistivity of the system. This leads to Joule’s law, i.e., the heat produced by currents is proportional to the resistivity and the square of currents.
doi_str_mv 10.1063/1.4919967
format article
fullrecord <record><control><sourceid>proquest_osti_</sourceid><recordid>TN_cdi_osti_scitechconnect_22403138</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>3781668031</sourcerecordid><originalsourceid>FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243</originalsourceid><addsrcrecordid>eNp9kT9PwzAQxS0EEqUw8A0sMTGk-BwntkdU8adSgQUGJst1bHCVxqntIPXbk6qV2Jhu-b13d-8hdA1kBqQu72DGJEhZ8xM0ASJkwetKnKIJIZQWlAlxji5SWhMCIBiboM8Xb2JIJvTeYBO6ZjDZ__i8w8HhVufsjcXOxo0PXcI6Y7sdfOtX0Q-bGV7M8GvoCt9lG_Uo7L5wr-OoaW26RGdOt8leHecUfTw-vM-fi-Xb02J-vyxMCWUuGs55KYA1thK0YZUxQjRMVkRrUcJqJQSF2kkmJGOs0qaWztWGGNo0vHaUlVN0c_ANKXuVjM_WfI-fdNZkRSkj4xrxR_UxbAebslqHIXbjYYoCZbySRJD_KOCkgtGLwEjdHqh9cilap_roNzruFBC1b0GBOrZQ_gJI9HeG</addsrcrecordid><sourcetype>Open Access Repository</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>1705103101</pqid></control><display><type>article</type><title>Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles</title><source>American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list)</source><source>AIP_美国物理联合会现刊(与NSTL共建)</source><creator>Bru, J.-B. ; de Siqueira Pedra, W. ; Hertling, C.</creator><creatorcontrib>Bru, J.-B. ; de Siqueira Pedra, W. ; Hertling, C.</creatorcontrib><description>We consider free lattice fermions subjected to a static bounded potential and a time- and space-dependent electric field. For any bounded convex region ℛ ⊂ ℝd (d ≥ 1) of space, electric fields E within R drive currents. At leading order, uniformly with respect to the volume R of R and the particular choice of the static potential, the dependency on E of the current is linear and described by a conductivity (tempered, operator-valued) distribution. Because of the positivity of the heat production, the real part of its Fourier transform is a positive measure, named here (microscopic) conductivity measure of R, in accordance with Ohm’s law in Fourier space. This finite measure is the Fourier transform of a time-correlation function of current fluctuations, i.e., the conductivity distribution satisfies Green–Kubo relations. We additionally show that this measure can also be seen as the boundary value of the Laplace–Fourier transform of a so-called quantum current viscosity. The real and imaginary parts of conductivity distributions are related to each other via the Hilbert transform, i.e., they satisfy Kramers–Kronig relations. At leading order, uniformly with respect to parameters, the heat production is the classical work performed by electric fields on the system in presence of currents. The conductivity measure is uniformly bounded with respect to parameters of the system and it is never the trivial measure 0 dν. Therefore, electric fields generally produce heat in such systems. In fact, the conductivity measure defines a quadratic form in the space of Schwartz functions, the Legendre–Fenchel transform of which describes the resistivity of the system. This leads to Joule’s law, i.e., the heat produced by currents is proportional to the resistivity and the square of currents.</description><identifier>ISSN: 0022-2488</identifier><identifier>EISSN: 1089-7658</identifier><identifier>DOI: 10.1063/1.4919967</identifier><language>eng</language><publisher>New York: American Institute of Physics</publisher><subject>CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS ; Conductivity ; Correlation analysis ; CORRELATION FUNCTIONS ; ELECTRIC FIELDS ; Electrical resistivity ; FERMIONS ; Fourier law ; FOURIER TRANSFORMATION ; Fourier transforms ; HEAT PRODUCTION ; Hilbert transformation ; Operators (mathematics) ; Parameters ; Physics ; Quadratic forms ; SPACE DEPENDENCE ; Time correlation functions ; Time dependence ; Variation ; Viscosity</subject><ispartof>Journal of mathematical physics, 2015-05, Vol.56 (5), p.1</ispartof><rights>Copyright American Institute of Physics May 2015</rights><rights>2015 AIP Publishing LLC.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243</citedby><cites>FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243</cites><orcidid>0000-0002-1090-8982</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>230,314,780,782,784,885,27924,27925</link.rule.ids><backlink>$$Uhttps://www.osti.gov/biblio/22403138$$D View this record in Osti.gov$$Hfree_for_read</backlink></links><search><creatorcontrib>Bru, J.-B.</creatorcontrib><creatorcontrib>de Siqueira Pedra, W.</creatorcontrib><creatorcontrib>Hertling, C.</creatorcontrib><title>Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles</title><title>Journal of mathematical physics</title><description>We consider free lattice fermions subjected to a static bounded potential and a time- and space-dependent electric field. For any bounded convex region ℛ ⊂ ℝd (d ≥ 1) of space, electric fields E within R drive currents. At leading order, uniformly with respect to the volume R of R and the particular choice of the static potential, the dependency on E of the current is linear and described by a conductivity (tempered, operator-valued) distribution. Because of the positivity of the heat production, the real part of its Fourier transform is a positive measure, named here (microscopic) conductivity measure of R, in accordance with Ohm’s law in Fourier space. This finite measure is the Fourier transform of a time-correlation function of current fluctuations, i.e., the conductivity distribution satisfies Green–Kubo relations. We additionally show that this measure can also be seen as the boundary value of the Laplace–Fourier transform of a so-called quantum current viscosity. The real and imaginary parts of conductivity distributions are related to each other via the Hilbert transform, i.e., they satisfy Kramers–Kronig relations. At leading order, uniformly with respect to parameters, the heat production is the classical work performed by electric fields on the system in presence of currents. The conductivity measure is uniformly bounded with respect to parameters of the system and it is never the trivial measure 0 dν. Therefore, electric fields generally produce heat in such systems. In fact, the conductivity measure defines a quadratic form in the space of Schwartz functions, the Legendre–Fenchel transform of which describes the resistivity of the system. This leads to Joule’s law, i.e., the heat produced by currents is proportional to the resistivity and the square of currents.</description><subject>CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS</subject><subject>Conductivity</subject><subject>Correlation analysis</subject><subject>CORRELATION FUNCTIONS</subject><subject>ELECTRIC FIELDS</subject><subject>Electrical resistivity</subject><subject>FERMIONS</subject><subject>Fourier law</subject><subject>FOURIER TRANSFORMATION</subject><subject>Fourier transforms</subject><subject>HEAT PRODUCTION</subject><subject>Hilbert transformation</subject><subject>Operators (mathematics)</subject><subject>Parameters</subject><subject>Physics</subject><subject>Quadratic forms</subject><subject>SPACE DEPENDENCE</subject><subject>Time correlation functions</subject><subject>Time dependence</subject><subject>Variation</subject><subject>Viscosity</subject><issn>0022-2488</issn><issn>1089-7658</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><recordid>eNp9kT9PwzAQxS0EEqUw8A0sMTGk-BwntkdU8adSgQUGJst1bHCVxqntIPXbk6qV2Jhu-b13d-8hdA1kBqQu72DGJEhZ8xM0ASJkwetKnKIJIZQWlAlxji5SWhMCIBiboM8Xb2JIJvTeYBO6ZjDZ__i8w8HhVufsjcXOxo0PXcI6Y7sdfOtX0Q-bGV7M8GvoCt9lG_Uo7L5wr-OoaW26RGdOt8leHecUfTw-vM-fi-Xb02J-vyxMCWUuGs55KYA1thK0YZUxQjRMVkRrUcJqJQSF2kkmJGOs0qaWztWGGNo0vHaUlVN0c_ANKXuVjM_WfI-fdNZkRSkj4xrxR_UxbAebslqHIXbjYYoCZbySRJD_KOCkgtGLwEjdHqh9cilap_roNzruFBC1b0GBOrZQ_gJI9HeG</recordid><startdate>20150501</startdate><enddate>20150501</enddate><creator>Bru, J.-B.</creator><creator>de Siqueira Pedra, W.</creator><creator>Hertling, C.</creator><general>American Institute of Physics</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7U5</scope><scope>8FD</scope><scope>H8D</scope><scope>JQ2</scope><scope>L7M</scope><scope>OTOTI</scope><orcidid>https://orcid.org/0000-0002-1090-8982</orcidid></search><sort><creationdate>20150501</creationdate><title>Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles</title><author>Bru, J.-B. ; de Siqueira Pedra, W. ; Hertling, C.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2015</creationdate><topic>CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS</topic><topic>Conductivity</topic><topic>Correlation analysis</topic><topic>CORRELATION FUNCTIONS</topic><topic>ELECTRIC FIELDS</topic><topic>Electrical resistivity</topic><topic>FERMIONS</topic><topic>Fourier law</topic><topic>FOURIER TRANSFORMATION</topic><topic>Fourier transforms</topic><topic>HEAT PRODUCTION</topic><topic>Hilbert transformation</topic><topic>Operators (mathematics)</topic><topic>Parameters</topic><topic>Physics</topic><topic>Quadratic forms</topic><topic>SPACE DEPENDENCE</topic><topic>Time correlation functions</topic><topic>Time dependence</topic><topic>Variation</topic><topic>Viscosity</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Bru, J.-B.</creatorcontrib><creatorcontrib>de Siqueira Pedra, W.</creatorcontrib><creatorcontrib>Hertling, C.</creatorcontrib><collection>CrossRef</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>ProQuest Computer Science Collection</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>OSTI.GOV</collection><jtitle>Journal of mathematical physics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Bru, J.-B.</au><au>de Siqueira Pedra, W.</au><au>Hertling, C.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles</atitle><jtitle>Journal of mathematical physics</jtitle><date>2015-05-01</date><risdate>2015</risdate><volume>56</volume><issue>5</issue><spage>1</spage><pages>1-</pages><issn>0022-2488</issn><eissn>1089-7658</eissn><abstract>We consider free lattice fermions subjected to a static bounded potential and a time- and space-dependent electric field. For any bounded convex region ℛ ⊂ ℝd (d ≥ 1) of space, electric fields E within R drive currents. At leading order, uniformly with respect to the volume R of R and the particular choice of the static potential, the dependency on E of the current is linear and described by a conductivity (tempered, operator-valued) distribution. Because of the positivity of the heat production, the real part of its Fourier transform is a positive measure, named here (microscopic) conductivity measure of R, in accordance with Ohm’s law in Fourier space. This finite measure is the Fourier transform of a time-correlation function of current fluctuations, i.e., the conductivity distribution satisfies Green–Kubo relations. We additionally show that this measure can also be seen as the boundary value of the Laplace–Fourier transform of a so-called quantum current viscosity. The real and imaginary parts of conductivity distributions are related to each other via the Hilbert transform, i.e., they satisfy Kramers–Kronig relations. At leading order, uniformly with respect to parameters, the heat production is the classical work performed by electric fields on the system in presence of currents. The conductivity measure is uniformly bounded with respect to parameters of the system and it is never the trivial measure 0 dν. Therefore, electric fields generally produce heat in such systems. In fact, the conductivity measure defines a quadratic form in the space of Schwartz functions, the Legendre–Fenchel transform of which describes the resistivity of the system. This leads to Joule’s law, i.e., the heat produced by currents is proportional to the resistivity and the square of currents.</abstract><cop>New York</cop><pub>American Institute of Physics</pub><doi>10.1063/1.4919967</doi><orcidid>https://orcid.org/0000-0002-1090-8982</orcidid><oa>free_for_read</oa></addata></record>
fulltext fulltext
identifier ISSN: 0022-2488
ispartof Journal of mathematical physics, 2015-05, Vol.56 (5), p.1
issn 0022-2488
1089-7658
language eng
recordid cdi_osti_scitechconnect_22403138
source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP_美国物理联合会现刊(与NSTL共建)
subjects CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Conductivity
Correlation analysis
CORRELATION FUNCTIONS
ELECTRIC FIELDS
Electrical resistivity
FERMIONS
Fourier law
FOURIER TRANSFORMATION
Fourier transforms
HEAT PRODUCTION
Hilbert transformation
Operators (mathematics)
Parameters
Physics
Quadratic forms
SPACE DEPENDENCE
Time correlation functions
Time dependence
Variation
Viscosity
title Microscopic conductivity of lattice fermions at equilibrium. I. Non-interacting particles
url http://sfxeu10.hosted.exlibrisgroup.com/loughborough?ctx_ver=Z39.88-2004&ctx_enc=info:ofi/enc:UTF-8&ctx_tim=2025-01-06T05%3A58%3A34IST&url_ver=Z39.88-2004&url_ctx_fmt=infofi/fmt:kev:mtx:ctx&rfr_id=info:sid/primo.exlibrisgroup.com:primo3-Article-proquest_osti_&rft_val_fmt=info:ofi/fmt:kev:mtx:journal&rft.genre=article&rft.atitle=Microscopic%20conductivity%20of%20lattice%20fermions%20at%20equilibrium.%20I.%20Non-interacting%20particles&rft.jtitle=Journal%20of%20mathematical%20physics&rft.au=Bru,%20J.-B.&rft.date=2015-05-01&rft.volume=56&rft.issue=5&rft.spage=1&rft.pages=1-&rft.issn=0022-2488&rft.eissn=1089-7658&rft_id=info:doi/10.1063/1.4919967&rft_dat=%3Cproquest_osti_%3E3781668031%3C/proquest_osti_%3E%3Cgrp_id%3Ecdi_FETCH-LOGICAL-c313t-d7773814de582d45cc88d4950aa831bb88216f94894445ac69ff6c0c2dd76f243%3C/grp_id%3E%3Coa%3E%3C/oa%3E%3Curl%3E%3C/url%3E&rft_id=info:oai/&rft_pqid=1705103101&rft_id=info:pmid/&rfr_iscdi=true