Magnetic properties of single atoms of Fe and Co on Ir(111) and Pt(111)

Etz, Corina; Zabloudil, J.; Weinberger, P.; Vedmedenko, E. Y.

doi:10.1103/physrevb.77.184425

Cited by 44 publications

(53 citation statements)

References 32 publications

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“…We should point out that our setup differs considerably from that used in previous calculations 4,31,32,34 of the magnetic anisotropy of supported nanostructures. Most of these calculations are based on a KKR Green's-function approach, a local exchange-correlation functional, a complete neglect of relaxation of the adsorbate/substrate complex, and the use of the magnetic force theorem for calculating the magnetic anisotropy energy.…”

Section: Computational Setupmentioning

confidence: 94%

“…4,21,[30][31][32][33][34][35] With the exception of our recent work 30 and the work by Shick and Lichtenstein 35 and by Balashov et al, 21 all these calculations are based on a Green's-function approach within the screened fully relativistic Kohn-Korringa-Rostocker ͑KKR͒ method, an idealized geometry propagating the bulk structure of the substrate, the local-density approximation, and the use of the magnetic force theorem. 4,21,[31][32][33][34][35] In our recent assessment of the impact of the different approximations, we have demonstrated that the most important step is the description of the adsorbate/ substrate complex. Calculations based on the assumption of an idealized bulklike geometry essentially attempt to cure a defect of the SDFT ͑missing orbital dependence of the exchange field͒ by artificially minimizing adatom/support hybridization.…”

Section: Introductionmentioning

confidence: 99%

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Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

et al. 2010

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We performed a combined theoretical and experimental investigation of the orbital magnetism and magnetocrystalline anisotropy of isolated Co and Fe adatoms on Pd͑111͒ and Rh͑111͒. Theoretical calculations of the spin and orbital moments are based on ab initio spin-polarized density-functional theory ͑DFT͒ including a self-consistent treatment of spin-orbit coupling. The calculations use a slab model to represent the adsorbate/ substrate complex and allow for a complete structural relaxation leading to a strong inward displacement of the adatom and modest vertical and lateral relaxations in the substrate atoms. Compared to an idealized geometry where the atoms are kept on bulk lattice positions up to the surface, relaxation leads to a much stronger adatom/ligand hybridization. This is also reflected in the results for orbital moments and magnetocrystalline anisotropy energy ͑MAE͒. The enhanced hybridization leads to strong quenching of the adatom orbital moments but also to the formation of large induced spin and orbital moments in the substrate. As a consequence, we find that the substrate contribution to the MAE is much more important than estimated before on the basis of studies using an idealized geometry. We also find the surprising result that the MAE strongly depends on the adsorption site. The magnitude and even the sign of the MAE change for adatoms on face-centered cubic with respect to the ones on hexagonal close-packed hollow sites on the ͑111͒ surface. The dependence of the MAE on the combination of adatom and substrate has been analyzed in terms of the electronic structure, leading to a sound physical picture of the origin of the MAE. A fundamental problem, however, is the correct prediction of the size of the orbital moments of the adatoms. We suggest that this problem can be solved only via post-DFT corrections introducing an orbital dependence of the exchange potential. The theoretical results are compared to site-averaged, element-specific x-ray magnetic circular dichroism ͑XMCD͒ measurements. Lowtemperature XMCD spectra and magnetization curves reveal weak out-of-plane anisotropy for Fe adatoms on both substrates. Interestingly, Co adatoms on Rh͑111͒ present in-plane anisotropy with MAE of about −0.6 meV, contrary to the known out-of-plane anisotropy of Co on Pd͑111͒ and Pt͑111͒. The orbital to spin magnetic-moment ratio measured by XMCD shows that the Co adatoms present much stronger orbital magnetization components compared to Fe. The connection between orbital moments and MAE is discussed at the theoretical level including the contribution of the induced substrate magnetization.

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Section: Computational Setupmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

et al. 2010

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“…They treated Co in different configurations and environments, like Co 075407-6 overlayers on Pt(111) 35 , Co nano wires attached to Pt(111) step edges 36,37 and isolated Co adatoms on bare Pt(111) surfaces. 38,39 Even though these configurations have different coordination numbers of underlying Pt atoms per Co atom, they show consistently an induced spin moment M spin of the nearest-neighbor Pt atoms in the range from 0.1 to 0.3 μ B , which is about 1 order of magnitude larger than the orbital moments M orb . Therefore the total induced magnetic moment M Pt of Pt atoms is mainly determined by the spin moment M spin .…”

Section: Discussionmentioning

confidence: 99%

Spin polarization of platinum (111) induced by the proximity to cobalt nanostripes

et al. 2011

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We measured a spin polarization above a Pt(111) surface in the vicinity of a Co nanostripe by spin-polarized scanning tunneling spectroscopy. The spin polarization exponentially decays away from the Pt-Co interface and is detectable at distances larger than 1 nm. By performing self-consistent ab initio calculations of the electronic structure for a related model system we reveal the interplay between the induced magnetic moments within the Pt surface and the spin-resolved electronic density of states above the surface.

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“…The magnetic properties (spin and orbital moments, magnetic anisotropy energy) of a free surface of Co adlayers or of Co clusters on Pt(111) were already studied extensively in the past [22][23][24]. However, viewed as sample system in an STM experiment, the situation becomes less straight forward, since as already was mentioned a tip with a lead has to be included.…”

Section: Stacking Systemsmentioning

confidence: 99%

A theoretical STM study of Co_n/Pt(111)

Weinberger¹

2011

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Magnetic properties of single atoms of Fe and Co on Ir(111) and Pt(111)

Cited by 44 publications

References 32 publications

Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

Spin polarization of platinum (111) induced by the proximity to cobalt nanostripes

A theoretical STM study of Co_n/Pt(111)

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Magnetic properties of single atoms of Fe and Co on Ir(111) and Pt(111)

Cited by 44 publications

References 32 publications

Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

Magnetocrystalline anisotropy energy of Co and Fe adatoms on the (111) surfaces of Pd and Rh

Spin polarization of platinum (111) induced by the proximity to cobalt nanostripes

A theoretical STM study of Con/Pt(111)

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Resources

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A theoretical STM study of Co_n/Pt(111)