APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session D8: Spin Transport in Carbon-based Materials
2:30 PM–5:30 PM,
Monday, March 15, 2010
Room: Portland Ballroom 255
Sponsoring
Unit:
GMAG
Chair: Jing Shi, University of California, Riverside
Abstract ID: BAPS.2010.MAR.D8.2
Abstract: D8.00002 : Electronic spin transport, spin precession and spin relaxation in graphene field effect transistors
3:06 PM–3:42 PM
Preview Abstract
Abstract
Author:
Bart van wees
(university of groningen)
After an introduction of spintronics in graphene I will describe our recent
measurements of spin transport in graphene field effect transistors. Using a
non-local geometry, with seperated ferromagnet injector and detector
circuits, we were able to study the injection, transport, relaxation,
precession and detection of carrier spins in great detail, in both the
metallic electron and hole regimes as well as at the Dirac charge neutrality
point.
We found that:
a) Carriers can carry spins in graphene, with typical spin relaxation
lengths of 1 to 2 micrometers [1].
b) The spin relaxation times were found to be in the order of 100 to 200 ps,
and the spin relaxation of spins directed perpendicular to the graphene
plane was found to be slightly faster that spins oriented parallel to the
plane [2].
c) Spin transport occurs by diffusion. It was found however that carrier
drift, induced by applying large electric fields in the graphene layer could
speed up or slow down the transport of spins [3].
d) We found that the spin relaxation is most likely limited by the carrier
impurity potential scatterering, probably by the Elliot Yafet mechanism. No
appreciable change was observed in graphene nanoribbons down to 100 nm width
[4].
e) By changing the diffusion coefficient by changing the carrier density we
were able to observe that an increase in the diffusion constant, and thus in
the momentum scattering time, is accompanied by a similar increase in in the
spin relaxation time [5]. When extraploating these resulst to high mobility
(suspended) graphene, this implies that spin relaxation lengths approaching
100 micrometers might be possible at room temperature. Also it was found
that the diffusion constants for charge and spin are similar within less
than 10{\%}.
f) Finally I will present recent results where we compare spin transport in
single and N-layer graphene (with N ranging for 2 to 20) We find an increase
in the spin relaxation time when the number of layers is increased. Possible
mechanisms will be discussed.
[1] N. Tombros \textit{et al}., Nature 448, 571 (2007)
[2] N. Tombros \textit{et al.}, Phys. Rev. Lett. 101, 046601 (2008)
[3] C. Jozsa \textit{et al.}, Phys. Rev. Lett. 100, 236603 (2008), C. Jozsa \textit{et al}., Phys. Rev.
B79, 081402 (2009)
[4] M. Popinciuc \textit{et al.}, to be published in Phys. Rev. B, arXiv: 0908.1039
[5] C. Jozsa \textit{et al}., to be published in Phys. Rev. B, arXiv: 0910.1054
[6] T. Maassen, in preparation.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.D8.2