English

Proximity-induced magnetization in graphene: Towards efficient spin gating

Mesoscale and Nanoscale Physics 2020-11-17 v2 Materials Science

Abstract

Gate-tunable spin-dependent properties could be induced in graphene at room temperature through magnetic proximity effect by placing it in contact with a metallic ferromagnet. Because strong chemical bonding with the metallic substrate makes gating ineffective, an intervening passivation layer is needed. Previously considered passivation layers result in a large shift of the Dirac point away from the Fermi level, so that unrealistically large gate fields are required to tune the spin polarization in graphene. We show that a monolayer of Au or Pt used as the passivation layer between Co and graphene brings the Dirac point closer to the Fermi level. In the \Co/\Pt/\Gr system the proximity-induced spin polarization in graphene and its gate control are strongly enhanced by the presence of a surface band near the Fermi level. Furthermore, the shift of the Dirac point could be eliminated entirely by selecting submonolayer coverage in the passivation layer. Our findings open a path towards experimental realization of an optimized two-dimensional system with gate-tunable spin-dependent properties.

Keywords

Cite

@article{arxiv.2002.05569,
  title  = {Proximity-induced magnetization in graphene: Towards efficient spin gating},
  author = {Mihovil Bosnar and Ivor Lončarić and P. Lazić and K. D. Belashchenko and Igor Žutić},
  journal= {arXiv preprint arXiv:2002.05569},
  year   = {2020}
}

Comments

10 pages

R2 v1 2026-06-23T13:40:55.557Z