start-ver=1.4
cd-journal=joma
no-vol=18
cd-vols=
no-issue=9
article-no=
start-page=090101
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20250901
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Fundamentals and advances in transverse thermoelectrics
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Transverse thermoelectric effects interconvert charge and heat currents in orthogonal directions due to the breaking of either time-reversal symmetry or structural symmetry, enabling simple and versatile thermal energy harvesting and solid-state cooling/heating within single materials. In comparison to the complex module structures required for the conventional Seebeck and Peltier effects, the transverse thermoelectric effects provide the complete device structures, potentially resolving the fundamental issue of multi-module degradation of thermoelectric conversion performance. This review article provides an overview of all currently known transverse thermoelectric conversion phenomena and principles, as well as their characteristics, and reclassifies them in a unified manner. The performance of the transverse thermoelectric generator, refrigerator, and active cooler is formulated, showing that thermal boundary conditions play an essential role in discussion on their behaviors. Examples of recent application research and material development in transverse thermoelectrics are also introduced, followed by a discussion of future prospects.
en-copyright=
kn-copyright=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=AndoFuyuki
en-aut-sei=Ando
en-aut-mei=Fuyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=HiraiTakamasa
en-aut-sei=Hirai
en-aut-mei=Takamasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=ModakRajkumar
en-aut-sei=Modak
en-aut-mei=Rajkumar
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=GraysonMatthew A.
en-aut-sei=Grayson
en-aut-mei=Matthew A.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=UchidaKen-ichi
en-aut-sei=Uchida
en-aut-mei=Ken-ichi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

affil-num=1
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=

affil-num=2
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=

affil-num=3
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=

affil-num=4
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=

affil-num=5
en-affil=Department of Electrical and Computer Engineering, Northwestern University
kn-affil=

affil-num=6
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=
END

start-ver=1.4
cd-journal=joma
no-vol=26
cd-vols=
no-issue=1
article-no=
start-page=2535955
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20250807
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Quantitative measurements of transverse thermoelectric generation and cooling performances in SmCo5/Bi0.2Sb1.8Te3-based artificially tilted multilayer module
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=The transverse thermoelectric generation and cooling performances in a thermopile module composed of recently developed SmCo5/Bi0.2Sb1.8Te3 artificially tilted multilayers are evaluated quantitatively. When a large temperature difference of 405��C is applied to the SmCo5/Bi0.2Sb1.8Te3-based module, the open-circuit voltage and output power reach 0.51?V and 0.80 W, respectively. The corresponding maximum power density is 0.16 W/cm2, even if the power is normalized by the device area including areas that do not contribute to the power generation, such as epoxy resin, electrodes, and insulating layers. The maximum energy conversion efficiency for our module in this condition is experimentally determined to be 0.92%. Under the cooling operation, the same module exhibits the maximum temperature difference of 9.0��C and heat flow at the cold side of 1.6 W. Although these values are lower than the ideal thermoelectric performance expected from the material parameters due to the imperfections associated with modularization, the systematic investigations reported here clarify a potential of the SmCo5/Bi0.2Sb1.8Te3 artificially tilted multilayers as thermoelectric generators and cooling devices.
en-copyright=
kn-copyright=

en-aut-name=MurataMasayuki
en-aut-sei=Murata
en-aut-mei=Masayuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=AndoFuyuki
en-aut-sei=Ando
en-aut-mei=Fuyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=HiraiTakamasa
en-aut-sei=Hirai
en-aut-mei=Takamasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=UchidaKen-ichi
en-aut-sei=Uchida
en-aut-mei=Ken-ichi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

affil-num=1
en-affil=Research Institute for Energy Conservation, National Institute of Advanced Industrial Science and Technology
kn-affil=

affil-num=2
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=

affil-num=3
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=

affil-num=4
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=

affil-num=5
en-affil=Research Center for Magnetic and Spintronic Materials, National Institute for Materials Science
kn-affil=
en-keyword=Transverse thermoelectric generation
kn-keyword=Transverse thermoelectric generation
en-keyword=electronic cooling
kn-keyword=electronic cooling
en-keyword=thermoelectric module
kn-keyword=thermoelectric module
en-keyword=permanent magnet
kn-keyword=permanent magnet
END

start-ver=1.4
cd-journal=joma
no-vol=109
cd-vols=
no-issue=17
article-no=
start-page=174503
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2024
dt-pub=20240502
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Time-dependent Ginzburg-Landau theory of the vortex spin Hall effect
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=We develop a time-dependent Ginzburg-Landau theory of the vortex spin Hall effect, i.e., a spin Hall effect that is driven by the motion of superconducting vortices. For the direct vortex spin Hall effect in which an input charge current drives the transverse spin current accompanying the vortex motion, we start from the well-known Schmid-Caroli-Maki solution for the time-dependent Ginzburg-Landau equation under the applied electric field, and find out the expression of the induced spin current. For the inverse vortex spin Hall effect in which an input spin current drives the longitudinal vortex motion and produces the transverse charge current, we microscopically construct the time-dependent Ginzburg-Landau equation under the applied spin accumulation gradient, and calculate the induced transverse charge current as well as the open circuit voltage. The time-dependent Ginzburg-Landau equation and its analytical solution developed here can be a basis for more quantitative numerical simulations of the vortex spin Hall effect.
en-copyright=
kn-copyright=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=KatoYusuke
en-aut-sei=Kato
en-aut-mei=Yusuke
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=OheJun-ichiro
en-aut-sei=Ohe
en-aut-mei=Jun-ichiro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=IchiokaMasanori
en-aut-sei=Ichioka
en-aut-mei=Masanori
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

affil-num=1
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=

affil-num=2
en-affil=Department of Basic Science, University of Tokyo
kn-affil=

affil-num=3
en-affil=Department of Physics, Toho University
kn-affil=

affil-num=4
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=
END

start-ver=1.4
cd-journal=joma
no-vol=107
cd-vols=
no-issue=15
article-no=
start-page=155142
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2023
dt-pub=20230425
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Ginzburg-Landau action and polarization current in an excitonic insulator model of electronic ferroelectricity
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=In comparison to transport of spin polarization in ferromagnets, transport of electric polarization in ferroelectrics remains less explored. Taking an excitonic insulator model of electronic ferroelectricity as a prototypical example, we theoretically investigate the low-energy dynamics and transport of electric polarization by microscopically constructing the Ginzburg-Landau action. We show that, because of the scalar nature of the excitonic order parameter, only the longitudinal fluctuations are relevant to the transport of electric polarization. We also formulate the electric-polarization diffusion equation, in which the electric-polarization current is defined purely electronically without recourse to the lattice degrees of freedom.
en-copyright=
kn-copyright=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=IkedaNaoshi
en-aut-sei=Ikeda
en-aut-mei=Naoshi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=SaitohEiji
en-aut-sei=Saitoh
en-aut-mei=Eiji
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

affil-num=1
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=

affil-num=2
en-affil=Department of Physics, Okayama University
kn-affil=

affil-num=3
en-affil=Department of Applied Physics, The University of Tokyo
kn-affil=
END

start-ver=1.4
cd-journal=joma
no-vol=105
cd-vols=
no-issue=10
article-no=
start-page=104417-1
end-page=104417-14
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2022
dt-pub=2022315
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Antiferromagnetic spin Seebeck effect across the spin-flop transition: A stochastic Ginzburg-Landau simulation
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=We investigate the antiferromagnetic spin Seebeck effect across the spin-flop transition in a numerical simulation based on the time-dependent Ginzburg-Landau equation for a bilayer of a uniaxial insulating antiferromagnet and an adjacent metal. By directly simulating the rate of change of the conduction-electron spin density s in the adjacent metal layer, we demonstrate that a sign reversal of the antiferromagnetic spin Seebeck effect across the spin-flop transition occurs when the interfacial coupling of s to the staggered magnetization n of the antiferromagnet dominates, whereas no sign reversal appears when the interfacial coupling of s to the magnetization m dominates. Moreover, we show that the sign reversal is influenced by the degree of spin dephasing in the metal layer. Our result indicates that the sign reversal is not a generic property of a simple uniaxial antiferromagnet, but controlled by microscopic details of the exchange coupling at the interface and the spin dephasing in the metal layer.
en-copyright=
kn-copyright=

en-aut-name=YamamotoYutaka
en-aut-sei=Yamamoto
en-aut-mei=Yutaka
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=IchiokaMasanori
en-aut-sei=Ichioka
en-aut-mei=Masanori
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

affil-num=1
en-affil=Department of Physics, Okayama University
kn-affil=

affil-num=2
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=

affil-num=3
en-affil=Research Institute for Interdisciplinary Science, Okayama University
kn-affil=
END

start-ver=1.4
cd-journal=joma
no-vol=12
cd-vols=
no-issue=1
article-no=
start-page=175
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2020
dt-pub=20200118
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Relation of Superconducting Pairing Symmetry and Non-Magnetic Impurity Effects in Vortex States
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Non-magnetic impurity scattering effects on the vortex core states are theoretically studied to clarify the contributions from the sign-change of the pairing function in anisotropic superconductors. The vortex states are calculated by the Eilenberger theory in superconductors with px-wave pairing symmetry, as well as the corresponding anisotropic s-wave symmetry. From the spatial structure of the pair potential and the local electronic states around a vortex, we examine the differences between anisotropic superconductors with and without sign-change of the pairing function, and estimate how twofold symmetric vortex core images change with increasing the impurity scattering rate both in the Born and the unitary limits. We found that twofold symmetric vortex core image of zero-energy local density of states changes the orientation of the twofold symmetry with increasing the scattering rate when the sign change occurs in the pairing function. Without the sign change, the vortex core shape reduces to circular one with approaching dirty cases. These results of the impurity effects are valuable for identifying the pairing symmetry by observation of the vortex core image by the STM observation.
en-copyright=
kn-copyright=

en-aut-name=SeraYasuaki
en-aut-sei=Sera
en-aut-mei=Yasuaki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=UedaTakahiro
en-aut-sei=Ueda
en-aut-mei=Takahiro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=AdachiHiroto
en-aut-sei=Adachi
en-aut-mei=Hiroto
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=IchiokaMasanori
en-aut-sei=Ichioka
en-aut-mei=Masanori
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

affil-num=1
en-affil=Department of Physics, Okayama University
kn-affil=

affil-num=2
en-affil=Department of Physics, Okayama University
kn-affil=

affil-num=3
en-affil=Department of Physics, Okayama University
kn-affil=

affil-num=4
en-affil=Department of Physics, Okayama University
kn-affil=
en-keyword=unconventional superconductivity
kn-keyword=unconventional superconductivity
en-keyword=pairing symmetry
kn-keyword=pairing symmetry
en-keyword=vortex states
kn-keyword=vortex states
en-keyword=non-magnetic impurity scattering
kn-keyword=non-magnetic impurity scattering
END