Transformation of spin information into large electrical signals using carbon nanotubes

Spin electronics (spintronics) exploits the magnetic nature of electrons, and this principle is commercially applied in, for example, the spin valves of disk-drive read heads. There is currently widespread interest in developing new types of spintronic devices based on industrially relevant semicond...

Full description

Saved in:
Bibliographic Details
Published in:Nature 2007-01, Vol.445 (7126), p.410-413
Main Authors: HUESO, Luis E, PRUNEDA, José M, FERRARI, Valeria, BURNELL, Gavin, VALDES-HERRERA, José P, SIMONS, Benjamin D, LITTLEWOOD, Peter B, ARTACHO, Emilio, FERT, Albert, MATHUR, Neil D
Format: Article
Language:English
Subjects:
Applied sciences
Carbon
Channels
Devices
Electrodes
Electronics
Electronics industry
Electrons
Exact sciences and technology
Injection
Magnetism
Magnetoelectric, magnetostrictive, magnetoacoustic, magnetooptic and magnetothermal devices. Spintronics
Manganites
Materials selection
Miscellaneous
Molecular electronics, nanoelectronics
Nanotechnology
Nanotubes
Particle physics
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Semiconductors
Spintronics
Storage and reproduction of information
Transformations
Valves
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Spin electronics (spintronics) exploits the magnetic nature of electrons, and this principle is commercially applied in, for example, the spin valves of disk-drive read heads. There is currently widespread interest in developing new types of spintronic devices based on industrially relevant semiconductors, in which a spin-polarized current flows through a lateral channel between a spin-polarized source and drain. However, the transformation of spin information into large electrical signals is limited by spin relaxation, so that the magnetoresistive signals are below 1% (ref. 2). Here we report large magnetoresistance effects (61% at 5 K), which correspond to large output signals (65 mV), in devices where the non-magnetic channel is a multiwall carbon nanotube that spans a 1.5 microm gap between epitaxial electrodes of the highly spin polarized manganite La(0.7)Sr(0.3)MnO3. This spintronic system combines a number of favourable properties that enable this performance; the long spin lifetime in nanotubes due to the small spin-orbit coupling of carbon; the high Fermi velocity in nanotubes that limits the carrier dwell time; the high spin polarization in the manganite electrodes, which remains high right up to the manganite-nanotube interface; and the resistance of the interfacial barrier for spin injection. We support these conclusions regarding the interface using density functional theory calculations. The success of our experiments with such chemically and geometrically different materials should inspire new avenues in materials selection for future spintronics applications.
ISSN:0028-0836
1476-4687
1476-4679
DOI:10.1038/nature05507