We investigated the magnetic behaviour of an Fe overlayer on a Ni buffer layer (Fe/Ni multilayer system) grown on top of the Fe -p(1 x 1)O surface, with a particular focus on the modifications observed in the spin-resolved electronic structure and the role of oxygen, introduced in the system in a well-defined amount at the sub-strate preparation stage. The structural properties are investigated by means of low energy electron diffraction, that confirms the formation of an epitaxial system featuring a metastable surface lattice. Spin-resolved photo emission spectroscopy testifies a strong decrease of the spectral spin polarization for increasing thickness of Ni buffer layer, reaching a minimum from a nominal thickness of 6 Ni atomic layers. Surprisingly, the growth single Fe overlayer is sufficient to restore most of the original polarization signal, thus creating an ultrathin Fe film seemingly decoupled from the substrate. Ab initio calculations track the modifications of the magnetic moments of the surface layers that quench upon Ni deposition and restore with additional Fe growth. Spin resolved inverse photoemission highlights a notable reduction of the density of majority states just above Fermi level, possibly influencing the magnetic response of the system.
Oxygen contribution to the magnetic response of ultrathin Fe/Ni multilayers grown on Fe-p(1 × 1)O / F. Goto, G. Perozzi, A. Calloni, G. Albani, G. Fratesi, S. Achilli, L. Duò, M. Finazzi, F. Ciccacci, G. Bussetti. - In: APPLIED SURFACE SCIENCE. - ISSN 0169-4332. - 606:(2022 Dec 30), pp. 154735.1-154735.11. [10.1016/j.apsusc.2022.154735]
Oxygen contribution to the magnetic response of ultrathin Fe/Ni multilayers grown on Fe-p(1 × 1)O
G. Fratesi;S. Achilli;
2022
Abstract
We investigated the magnetic behaviour of an Fe overlayer on a Ni buffer layer (Fe/Ni multilayer system) grown on top of the Fe -p(1 x 1)O surface, with a particular focus on the modifications observed in the spin-resolved electronic structure and the role of oxygen, introduced in the system in a well-defined amount at the sub-strate preparation stage. The structural properties are investigated by means of low energy electron diffraction, that confirms the formation of an epitaxial system featuring a metastable surface lattice. Spin-resolved photo emission spectroscopy testifies a strong decrease of the spectral spin polarization for increasing thickness of Ni buffer layer, reaching a minimum from a nominal thickness of 6 Ni atomic layers. Surprisingly, the growth single Fe overlayer is sufficient to restore most of the original polarization signal, thus creating an ultrathin Fe film seemingly decoupled from the substrate. Ab initio calculations track the modifications of the magnetic moments of the surface layers that quench upon Ni deposition and restore with additional Fe growth. Spin resolved inverse photoemission highlights a notable reduction of the density of majority states just above Fermi level, possibly influencing the magnetic response of the system.File | Dimensione | Formato | |
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