Metallicity without quasi-particles in room-temperature strontium titanate

Metallicity without quasi-particles in room-temperature strontium titanate

Correlated matter: When metals go bad An expected metallic behavior that defies existing theory is observed by researchers in France. Xiao Lin from the Laboratoire Physique et Etude de Matériaux and co-workers show that room temperature strontium titanate behaves like a so-called ‘bad’ metal. Partic...

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Main Authors: Xiao Lin, Carl Willem Rischau, Lisa Buchauer, Alexandre Jaoui, Benoît Fauqué, Kamran Behnia
Format: Article
Language:English
Published: Nature Publishing Group 2017-07-01
Series:npj Quantum Materials
Online Access:https://doi.org/10.1038/s41535-017-0044-5
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spelling doaj-8a5e1a74bf33430686500c7f43dcf4252021-04-02T16:13:55ZengNature Publishing Groupnpj Quantum Materials2397-46482017-07-01211810.1038/s41535-017-0044-5Metallicity without quasi-particles in room-temperature strontium titanateXiao Lin0Carl Willem Rischau1Lisa Buchauer2Alexandre Jaoui3Benoît Fauqué4Kamran Behnia5Laboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityLaboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityLaboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityLaboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityLaboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityLaboratoire Physique et Etude de Matériaux (CNRS-UPMC), ESPCI Paris, PSL Research UniversityCorrelated matter: When metals go bad An expected metallic behavior that defies existing theory is observed by researchers in France. Xiao Lin from the Laboratoire Physique et Etude de Matériaux and co-workers show that room temperature strontium titanate behaves like a so-called ‘bad’ metal. Particles with an electric charge can flow through a metal with little resistance. But this resistivity increases with particle density. In conventional metals, this increase eventually stops at what is known as the Mott-Ioffe-Regel limit. Bad or strange metals, however, defy this rule and the resistivity continues to increase. This effect is thought to arise when the when the electrons work collectively, creating quasi-particles. Lin and colleagues show that this bad metal behavior can occur even in a material without quasi-particles. Instead, they argue the metallicity is caused by so-called Landauer transmission between individual dopants.https://doi.org/10.1038/s41535-017-0044-5
collection DOAJ
language English
format Article
sources DOAJ
author Xiao Lin
Carl Willem Rischau
Lisa Buchauer
Alexandre Jaoui
Benoît Fauqué
Kamran Behnia
spellingShingle Xiao Lin
Carl Willem Rischau
Lisa Buchauer
Alexandre Jaoui
Benoît Fauqué
Kamran Behnia
Metallicity without quasi-particles in room-temperature strontium titanate
npj Quantum Materials
author_facet Xiao Lin
Carl Willem Rischau
Lisa Buchauer
Alexandre Jaoui
Benoît Fauqué
Kamran Behnia
author_sort Xiao Lin
title Metallicity without quasi-particles in room-temperature strontium titanate
title_short Metallicity without quasi-particles in room-temperature strontium titanate
title_full Metallicity without quasi-particles in room-temperature strontium titanate
title_fullStr Metallicity without quasi-particles in room-temperature strontium titanate
title_full_unstemmed Metallicity without quasi-particles in room-temperature strontium titanate
title_sort metallicity without quasi-particles in room-temperature strontium titanate
publisher Nature Publishing Group
series npj Quantum Materials
issn 2397-4648
publishDate 2017-07-01
description Correlated matter: When metals go bad An expected metallic behavior that defies existing theory is observed by researchers in France. Xiao Lin from the Laboratoire Physique et Etude de Matériaux and co-workers show that room temperature strontium titanate behaves like a so-called ‘bad’ metal. Particles with an electric charge can flow through a metal with little resistance. But this resistivity increases with particle density. In conventional metals, this increase eventually stops at what is known as the Mott-Ioffe-Regel limit. Bad or strange metals, however, defy this rule and the resistivity continues to increase. This effect is thought to arise when the when the electrons work collectively, creating quasi-particles. Lin and colleagues show that this bad metal behavior can occur even in a material without quasi-particles. Instead, they argue the metallicity is caused by so-called Landauer transmission between individual dopants.
url https://doi.org/10.1038/s41535-017-0044-5
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AT lisabuchauer metallicitywithoutquasiparticlesinroomtemperaturestrontiumtitanate
AT alexandrejaoui metallicitywithoutquasiparticlesinroomtemperaturestrontiumtitanate
AT benoitfauque metallicitywithoutquasiparticlesinroomtemperaturestrontiumtitanate
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