We report the magnetic response of FexCo1−x layer(s) intercalated under graphene, compared with the bulk equiatomic FeCo(1 0 0) specimen. Graphene grown on Ir(1 1 1) can act as a protective membrane, allowing confined epitaxial growth of homogeneous FexCo1−x layer(s). Few intercalated FexCo1−x layers exhibit a significant enhancement of the spin (Seff) and orbital (L) moments with respect to both the single elements and the bulk equiatomic FeCo(1 0 0) configuration, as demonstrated by means of magnetic circular dichroism experiments. Reducing the intercalant thickness down to a single layer of FexCo1−x, the easy magnetization direction switches from parallel to perpendicular to the surface plane, with a magnetic response being influenced by the underlying metal. Element-sensitive hysteresis loops disclose identical magnetization response at the Fe and Co sites, thus constituting a single magnetic unit with enhanced ferromagnetic response, with Fe acting as a strong ferromagnet, differently from its bulk bcc configuration. This is a significant step towards the control at the atomic scale of the magnetic response in low dimensional 3d transition metal alloys, with tunable easy-magnetization direction, enhanced spin moments and magnetic anisotropy, in a inert and protected configuration thanks to the 2D graphene cover.

Strong ferromagnetic coupling and tunable easy magnetization directions of FexCo1−x layer(s) intercalated under graphene / Avvisati, G.; Gargiani, P.; Lizzit, D.; Valvidares, M.; Lacovig, P.; Petrillo, C.; Sacchetti, F.; Betti, M. G.. - In: APPLIED SURFACE SCIENCE. - ISSN 0169-4332. - 527:(2020), p. 146599. [10.1016/j.apsusc.2020.146599]

Strong ferromagnetic coupling and tunable easy magnetization directions of FexCo1−x layer(s) intercalated under graphene

Betti M. G.
Supervision
2020

Abstract

We report the magnetic response of FexCo1−x layer(s) intercalated under graphene, compared with the bulk equiatomic FeCo(1 0 0) specimen. Graphene grown on Ir(1 1 1) can act as a protective membrane, allowing confined epitaxial growth of homogeneous FexCo1−x layer(s). Few intercalated FexCo1−x layers exhibit a significant enhancement of the spin (Seff) and orbital (L) moments with respect to both the single elements and the bulk equiatomic FeCo(1 0 0) configuration, as demonstrated by means of magnetic circular dichroism experiments. Reducing the intercalant thickness down to a single layer of FexCo1−x, the easy magnetization direction switches from parallel to perpendicular to the surface plane, with a magnetic response being influenced by the underlying metal. Element-sensitive hysteresis loops disclose identical magnetization response at the Fe and Co sites, thus constituting a single magnetic unit with enhanced ferromagnetic response, with Fe acting as a strong ferromagnet, differently from its bulk bcc configuration. This is a significant step towards the control at the atomic scale of the magnetic response in low dimensional 3d transition metal alloys, with tunable easy-magnetization direction, enhanced spin moments and magnetic anisotropy, in a inert and protected configuration thanks to the 2D graphene cover.
2020
Graphene; Intercalation; Nanomagnetism; Photoemission spectroscopy; X-ray magnetic circular dichroism
01 Pubblicazione su rivista::01a Articolo in rivista
Strong ferromagnetic coupling and tunable easy magnetization directions of FexCo1−x layer(s) intercalated under graphene / Avvisati, G.; Gargiani, P.; Lizzit, D.; Valvidares, M.; Lacovig, P.; Petrillo, C.; Sacchetti, F.; Betti, M. G.. - In: APPLIED SURFACE SCIENCE. - ISSN 0169-4332. - 527:(2020), p. 146599. [10.1016/j.apsusc.2020.146599]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1415522
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