Spin injection and perpendicular spin transport in graphite nanostructures

Tamalika Banerjee; Wilfred G. van der Wiel; Ron Jansen

doi:10.1103/PhysRevB.81.214409

Spin injection and perpendicular spin transport in graphite nanostructures

Tamalika Banerjee^*
, Wilfred G. van der Wiel
, Ron Jansen

^*Corresponding author for this work

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

33 Citations (Scopus)

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Abstract

Organic- and carbon-based materials are attractive for spintronics because their small spin-orbit coupling and low hyperfine interaction is expected to give rise to large spin-relaxation times. However, the corresponding spin-relaxation length is not necessarily large when transport is via weakly interacting molecular orbitals. Here we use graphite as a model system and study spin transport in the direction perpendicular to the weakly bonded graphene sheets. We achieve injection of highly (75%) spin-polarized electrons into graphite nano-structures of 300-500 nm across and up to 17 nm thick, and observe transport without any measurable loss of spin information. Direct visualization of local spin transport in graphite-based spin-valve sandwiches also shows spatially uniform and near-unity transmission for electrons at 1.8 eV above the Fermi level.

Original language	English
Article number	214409
Pages (from-to)	214409-1-214409-6
Number of pages	6
Journal	Physical Review. B: Condensed Matter and Materials Physics
Volume	81
Issue number	21
DOIs	https://doi.org/10.1103/PhysRevB.81.214409
Publication status	Published - 8-Jun-2010

Keywords

ELECTRON MAGNETIC MICROSCOPY
ROOM-TEMPERATURE
VALVE
SEMICONDUCTOR
SPINTRONICS
RELAXATION

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title = "Spin injection and perpendicular spin transport in graphite nanostructures",

abstract = "Organic- and carbon-based materials are attractive for spintronics because their small spin-orbit coupling and low hyperfine interaction is expected to give rise to large spin-relaxation times. However, the corresponding spin-relaxation length is not necessarily large when transport is via weakly interacting molecular orbitals. Here we use graphite as a model system and study spin transport in the direction perpendicular to the weakly bonded graphene sheets. We achieve injection of highly (75\%) spin-polarized electrons into graphite nano-structures of 300-500 nm across and up to 17 nm thick, and observe transport without any measurable loss of spin information. Direct visualization of local spin transport in graphite-based spin-valve sandwiches also shows spatially uniform and near-unity transmission for electrons at 1.8 eV above the Fermi level.",

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author = "Tamalika Banerjee and \{van der Wiel\}, \{Wilfred G.\} and Ron Jansen",

year = "2010",

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doi = "10.1103/PhysRevB.81.214409",

language = "English",

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AU - Banerjee, Tamalika

AU - van der Wiel, Wilfred G.

AU - Jansen, Ron

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N2 - Organic- and carbon-based materials are attractive for spintronics because their small spin-orbit coupling and low hyperfine interaction is expected to give rise to large spin-relaxation times. However, the corresponding spin-relaxation length is not necessarily large when transport is via weakly interacting molecular orbitals. Here we use graphite as a model system and study spin transport in the direction perpendicular to the weakly bonded graphene sheets. We achieve injection of highly (75%) spin-polarized electrons into graphite nano-structures of 300-500 nm across and up to 17 nm thick, and observe transport without any measurable loss of spin information. Direct visualization of local spin transport in graphite-based spin-valve sandwiches also shows spatially uniform and near-unity transmission for electrons at 1.8 eV above the Fermi level.

AB - Organic- and carbon-based materials are attractive for spintronics because their small spin-orbit coupling and low hyperfine interaction is expected to give rise to large spin-relaxation times. However, the corresponding spin-relaxation length is not necessarily large when transport is via weakly interacting molecular orbitals. Here we use graphite as a model system and study spin transport in the direction perpendicular to the weakly bonded graphene sheets. We achieve injection of highly (75%) spin-polarized electrons into graphite nano-structures of 300-500 nm across and up to 17 nm thick, and observe transport without any measurable loss of spin information. Direct visualization of local spin transport in graphite-based spin-valve sandwiches also shows spatially uniform and near-unity transmission for electrons at 1.8 eV above the Fermi level.

KW - ELECTRON MAGNETIC MICROSCOPY

KW - ROOM-TEMPERATURE

KW - VALVE

KW - SEMICONDUCTOR

KW - SPINTRONICS

KW - RELAXATION

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DO - 10.1103/PhysRevB.81.214409

M3 - Article

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JF - Physical Review. B: Condensed Matter and Materials Physics

IS - 21

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ER -

Spin injection and perpendicular spin transport in graphite nanostructures

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