Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals

Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals

The long spin-relaxation time (τs) toward the large transport distance of spin current (SC) is desirable for practical applications of spintronic devices because spatially and temporally large spin coherence makes spin manipulation easier. Here, we propose that nearly compensated metals (CMs) with e...

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Main Authors: Mst. Sanjida Aktar, Masamichi Sakai, Toshihiro Yoshizumi, Shigehiko Hasegawa
Format: Article
Language:English
Published: AIP Publishing LLC 2020-07-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/5.0013628
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spelling doaj-d9638d88b45343e2aa3c9ef8777f758c2020-11-25T03:18:25ZengAIP Publishing LLCAIP Advances2158-32262020-07-01107075210075210-1010.1063/5.0013628Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metalsMst. Sanjida Aktar0Masamichi Sakai1Toshihiro Yoshizumi2Shigehiko Hasegawa3Division of Material Science, Graduate School of Science and Engineering, Saitama University, Saitama 338-8570, JapanDivision of Material Science, Graduate School of Science and Engineering, Saitama University, Saitama 338-8570, JapanDivision of Material Science, Graduate School of Science and Engineering, Saitama University, Saitama 338-8570, JapanThe Institute of Scientific and Industrial Research, Osaka University, Ibaraki, Osaka 567-0047, JapanThe long spin-relaxation time (τs) toward the large transport distance of spin current (SC) is desirable for practical applications of spintronic devices because spatially and temporally large spin coherence makes spin manipulation easier. Here, we propose that nearly compensated metals (CMs) with electron–hole collisions accompanied by spin flipping have a potential mechanism that makes τs associated with the antiparallel SC extraordinarily long, where antiparallel SC is defined as the vector subtraction of hole and electron SCs. The present theoretical study on spin and charge transports in nearly CMs shows that (i) it is antiparallel SC that satisfies the Onsager reciprocal relation in combination with conventional charge current, (ii) both longitudinal and Hall resistivities are influenced by the enhancement of τs and are classified into two specific mechanisms, i.e., the conventional and the resonance Hall effect accompanied by a sustaining mode of antiparallel SC, and (iii) the resonance Hall effect is not influenced by the spin–orbit interaction unlike the non-resonance case. These findings indicate the potential of nearly CMs in application of spintronic materials.http://dx.doi.org/10.1063/5.0013628
collection DOAJ
language English
format Article
sources DOAJ
author Mst. Sanjida Aktar
Masamichi Sakai
Toshihiro Yoshizumi
Shigehiko Hasegawa
spellingShingle Mst. Sanjida Aktar
Masamichi Sakai
Toshihiro Yoshizumi
Shigehiko Hasegawa
Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
AIP Advances
author_facet Mst. Sanjida Aktar
Masamichi Sakai
Toshihiro Yoshizumi
Shigehiko Hasegawa
author_sort Mst. Sanjida Aktar
title Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
title_short Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
title_full Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
title_fullStr Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
title_full_unstemmed Spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
title_sort spin and charge transports with thermodynamic electron–hole correlation in nearly compensated metals
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2020-07-01
description The long spin-relaxation time (τs) toward the large transport distance of spin current (SC) is desirable for practical applications of spintronic devices because spatially and temporally large spin coherence makes spin manipulation easier. Here, we propose that nearly compensated metals (CMs) with electron–hole collisions accompanied by spin flipping have a potential mechanism that makes τs associated with the antiparallel SC extraordinarily long, where antiparallel SC is defined as the vector subtraction of hole and electron SCs. The present theoretical study on spin and charge transports in nearly CMs shows that (i) it is antiparallel SC that satisfies the Onsager reciprocal relation in combination with conventional charge current, (ii) both longitudinal and Hall resistivities are influenced by the enhancement of τs and are classified into two specific mechanisms, i.e., the conventional and the resonance Hall effect accompanied by a sustaining mode of antiparallel SC, and (iii) the resonance Hall effect is not influenced by the spin–orbit interaction unlike the non-resonance case. These findings indicate the potential of nearly CMs in application of spintronic materials.
url http://dx.doi.org/10.1063/5.0013628
work_keys_str_mv AT mstsanjidaaktar spinandchargetransportswiththermodynamicelectronholecorrelationinnearlycompensatedmetals
AT masamichisakai spinandchargetransportswiththermodynamicelectronholecorrelationinnearlycompensatedmetals
AT toshihiroyoshizumi spinandchargetransportswiththermodynamicelectronholecorrelationinnearlycompensatedmetals
AT shigehikohasegawa spinandchargetransportswiththermodynamicelectronholecorrelationinnearlycompensatedmetals
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