Lateral Spin Injection in Germanium Nanowires

Appelbaum I.; Awschalom D. D.; Brands M.; Costache M. V.; Dash S. P.; Datta S.; Dyakonov M. I.; Fert A; Fert A.; Grundler D.; Hall K. C.; Holleitner A. W.; Hueso L. E.; Johnson M.; Johnson M.; Jozsa C.; Kane B. E.; Kiselev A. A.; Koo H. C.; Lou X.; Min B. C.; Mohney S. E.; Schapers T.; Schliemann J.; Schmidt G.; Tanaka M.; Tutuc E.; Wolf S. A.; Zutic I.; Zwanenburg F. A.

slides

Lateral Spin Injection in Germanium Nanowires

Authors: Appelbaum I.
Awschalom D. D.
Brands M.
Costache M. V.
Dash S. P.
Datta S.
Dyakonov M. I.
Fert A
Fert A.
Grundler D.
Hall K. C.
Holleitner A. W.
Hueso L. E.
Johnson M.
Johnson M.
Jozsa C.
Kane B. E.
Kiselev A. A.
Koo H. C.
Lou X.
Min B. C.
Mohney S. E.
Schapers T.
Schliemann J.
Schmidt G.
Tanaka M.
Tutuc E.
Wolf S. A.
Zutic I.
Zwanenburg F. A.
Publication date: 24 August 2010
Publisher: 'American Chemical Society (ACS)'
Doi

Abstract

Electrical injection of spin-polarized electrons into a semiconductor, large spin diffusion length, and an integration friendly platform are desirable ingredients for spin-based devices. Here we demonstrate lateral spin injection and detection in germanium nanowires, by using ferromagnetic metal contacts and tunnel barriers for contact resistance engineering. Using data measured from over 80 samples, we map out the contact resistance window for which lateral spin transport is observed, manifestly showing the conductivity matching required for spin injection. Our analysis, based on the spin diffusion theory, indicates that the spin diffusion length is larger than 100 {\mu}m in germanium nanowires at 4.2 K

Similar works

Full text

Available Versions

Crossref

info:doi/10.1021%2Fnl1008663

Last time updated on 05/06/2019