Giant enhancement of spin accumulation and long-distance spin precession in metallic lateral spin valves

Yasuhiro Fukuma; Le Wang; Hiroshi Idzuchi; Saburo Takahashi; Sadamichi Maekawa; Yoshichika Otani

doi:10.1038/nmat3046

Giant enhancement of spin accumulation and long-distance spin precession in metallic lateral spin valves

Yasuhiro Fukuma, Le Wang, Hiroshi Idzuchi, Saburo Takahashi, Sadamichi Maekawa, Yoshichika Otani

Materials Property Division

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

164 Citations (Scopus)

Abstract

The non-local spin injection in lateral spin valves is strongly expected to be an effective method to generate a pure spin current for potential spintronic application. However, the spin-valve voltage, which determines the magnitude of the spin current flowing into an additional ferromagnetic wire, is typically of the order of 1μV. Here we show that lateral spin valves with low-resistivity NiFe/MgO/Ag junctions enable efficient spin injection with high applied current density, which leads to the spin-valve voltage increasing 100-fold. Hanle effect measurements demonstrate a long-distance collective 2π spin precession along a 6-μm-long Ag wire. These results suggest a route to faster and manipulable spin transport for the development of pure spin-current-based memory, logic and sensing devices.

Original language	English
Pages (from-to)	527-531
Number of pages	5
Journal	Nature Materials
Volume	10
Issue number	7
DOIs	https://doi.org/10.1038/nmat3046
Publication status	Published - 2011 Jul

ASJC Scopus subject areas

Chemistry(all)
Materials Science(all)
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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title = "Giant enhancement of spin accumulation and long-distance spin precession in metallic lateral spin valves",

abstract = "The non-local spin injection in lateral spin valves is strongly expected to be an effective method to generate a pure spin current for potential spintronic application. However, the spin-valve voltage, which determines the magnitude of the spin current flowing into an additional ferromagnetic wire, is typically of the order of 1μV. Here we show that lateral spin valves with low-resistivity NiFe/MgO/Ag junctions enable efficient spin injection with high applied current density, which leads to the spin-valve voltage increasing 100-fold. Hanle effect measurements demonstrate a long-distance collective 2π spin precession along a 6-μm-long Ag wire. These results suggest a route to faster and manipulable spin transport for the development of pure spin-current-based memory, logic and sensing devices.",

author = "Yasuhiro Fukuma and Le Wang and Hiroshi Idzuchi and Saburo Takahashi and Sadamichi Maekawa and Yoshichika Otani",

note = "Funding Information: This work is partly supported by the Grant-in-Aid for Scientific Research in Priority Area {\textquoteleft}Creation and control of spin current{\textquoteright} (No 19048013) from the Ministry of Education, Culture, Sports, Science and Technology, Japan.",

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AU - Fukuma, Yasuhiro

AU - Wang, Le

AU - Idzuchi, Hiroshi

AU - Takahashi, Saburo

AU - Maekawa, Sadamichi

AU - Otani, Yoshichika

N1 - Funding Information: This work is partly supported by the Grant-in-Aid for Scientific Research in Priority Area ‘Creation and control of spin current’ (No 19048013) from the Ministry of Education, Culture, Sports, Science and Technology, Japan.

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N2 - The non-local spin injection in lateral spin valves is strongly expected to be an effective method to generate a pure spin current for potential spintronic application. However, the spin-valve voltage, which determines the magnitude of the spin current flowing into an additional ferromagnetic wire, is typically of the order of 1μV. Here we show that lateral spin valves with low-resistivity NiFe/MgO/Ag junctions enable efficient spin injection with high applied current density, which leads to the spin-valve voltage increasing 100-fold. Hanle effect measurements demonstrate a long-distance collective 2π spin precession along a 6-μm-long Ag wire. These results suggest a route to faster and manipulable spin transport for the development of pure spin-current-based memory, logic and sensing devices.

AB - The non-local spin injection in lateral spin valves is strongly expected to be an effective method to generate a pure spin current for potential spintronic application. However, the spin-valve voltage, which determines the magnitude of the spin current flowing into an additional ferromagnetic wire, is typically of the order of 1μV. Here we show that lateral spin valves with low-resistivity NiFe/MgO/Ag junctions enable efficient spin injection with high applied current density, which leads to the spin-valve voltage increasing 100-fold. Hanle effect measurements demonstrate a long-distance collective 2π spin precession along a 6-μm-long Ag wire. These results suggest a route to faster and manipulable spin transport for the development of pure spin-current-based memory, logic and sensing devices.

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Giant enhancement of spin accumulation and long-distance spin precession in metallic lateral spin valves

Abstract

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