Abstract
Graphene is an attractive candidate in spintronics for a number of reasons, among which are its electric-field-controlled conductivity, its expected long spin lifetime and its two-dimensional nature. A number of recent proposals call for the development of high-quality ferromagnetic thin films in contact with graphene, whereas only thick polycrystalline or three-dimensional (nanoclusters) morphologies have been demonstrated so far. We report on the growth of flat, epitaxial ultrathin Co films on graphene using pulsed laser deposition. These display perpendicular magnetic anisotropy (PMA) in the thickness range 0.5–1 nm, in agreement with our first-principles calculations. PMA, epitaxy and ultra-small thickness bring new perspectives on graphene-based spintronic devices making use of the zero-field control of an arbitrary magnetization direction, band matching between electrodes and graphene, and interface phenomena such as the Rashba effect and electric field control of magnetism.
Highlights
To cite this version: Chi Vo-Van, Zoukaa Kassir-Bodon, Hongxing Yang, Johann Coraux, Jan Vogel, et al
We report the growth of flat, epitaxial ultrathin Co films on graphene
In this Letter we report the optimization of the epitaxial growth of Au-capped Co ultrathin films on graphene
Summary
To cite this version: Chi Vo-Van, Zoukaa Kassir-Bodon, Hongxing Yang, Johann Coraux, Jan Vogel, et al. PMA, epitaxy and ultrathin thickness bring new perspectives for graphene-based spintronic devices such as the zero-field control of an arbitrary magnetization direction, band matching between electrodes and graphene, and interface effects such as Rashba and electric field control of magnetism.
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