Observation of temperature-gradient-induced magnetization

Dazhi Hou; Zhiyong Qiu; R. Iguchi; K. Sato; E. K. Vehstedt; K. Uchida; G. E W Bauer; E. Saitoh

doi:10.1038/ncomms12265

Observation of temperature-gradient-induced magnetization

Dazhi Hou^*, Zhiyong Qiu, R. Iguchi, K. Sato, E. K. Vehstedt, K. Uchida, G. E W Bauer, E. Saitoh

^*Corresponding author for this work

QN/Bauer Group

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Applying magnetic fields has been the method of choice to magnetize non-magnetic materials, but they are difficult to focus. The magneto-electric effect and voltage-induced magnetization generate magnetization by applied electric fields, but only in special compounds or heterostructures. Here we demonstrate that a simple metal such as gold can be magnetized by a temperature gradient or magnetic resonance when in contact with a magnetic insulator by observing an anomalous Hall-like effect, which directly proves the breakdown of time-reversal symmetry. Such Hall measurements give experimental access to the spectral spin Hall conductance of the host metal, which is closely related to other spin caloritronics phenomena such as the spin Nernst effect and serves as a reference for theoretical calculation.

Original language	English
Article number	12265
Number of pages	6
Journal	Nature Communications
Volume	7
DOIs	https://doi.org/10.1038/ncomms12265
Publication status	Published - 26 Jul 2016

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abstract = "Applying magnetic fields has been the method of choice to magnetize non-magnetic materials, but they are difficult to focus. The magneto-electric effect and voltage-induced magnetization generate magnetization by applied electric fields, but only in special compounds or heterostructures. Here we demonstrate that a simple metal such as gold can be magnetized by a temperature gradient or magnetic resonance when in contact with a magnetic insulator by observing an anomalous Hall-like effect, which directly proves the breakdown of time-reversal symmetry. Such Hall measurements give experimental access to the spectral spin Hall conductance of the host metal, which is closely related to other spin caloritronics phenomena such as the spin Nernst effect and serves as a reference for theoretical calculation.",

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T1 - Observation of temperature-gradient-induced magnetization

AU - Hou, Dazhi

AU - Qiu, Zhiyong

AU - Iguchi, R.

AU - Sato, K.

AU - Vehstedt, E. K.

AU - Uchida, K.

AU - Bauer, G. E W

AU - Saitoh, E.

PY - 2016/7/26

Y1 - 2016/7/26

N2 - Applying magnetic fields has been the method of choice to magnetize non-magnetic materials, but they are difficult to focus. The magneto-electric effect and voltage-induced magnetization generate magnetization by applied electric fields, but only in special compounds or heterostructures. Here we demonstrate that a simple metal such as gold can be magnetized by a temperature gradient or magnetic resonance when in contact with a magnetic insulator by observing an anomalous Hall-like effect, which directly proves the breakdown of time-reversal symmetry. Such Hall measurements give experimental access to the spectral spin Hall conductance of the host metal, which is closely related to other spin caloritronics phenomena such as the spin Nernst effect and serves as a reference for theoretical calculation.

AB - Applying magnetic fields has been the method of choice to magnetize non-magnetic materials, but they are difficult to focus. The magneto-electric effect and voltage-induced magnetization generate magnetization by applied electric fields, but only in special compounds or heterostructures. Here we demonstrate that a simple metal such as gold can be magnetized by a temperature gradient or magnetic resonance when in contact with a magnetic insulator by observing an anomalous Hall-like effect, which directly proves the breakdown of time-reversal symmetry. Such Hall measurements give experimental access to the spectral spin Hall conductance of the host metal, which is closely related to other spin caloritronics phenomena such as the spin Nernst effect and serves as a reference for theoretical calculation.

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Observation of temperature-gradient-induced magnetization

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