Energetics of Co adatoms on the Cu(001) surface

Levanov, N. A.; Stepanyuk, V. S.; Hergert, W.; Бажанов, Д. И.; Dederichs, P. H.; Katsnelson, A. A.; Massobrio, Carlo

doi:10.1103/physrevb.61.2230

Cited by 130 publications

(95 citation statements)

References 26 publications

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“…(5) It includes the band energy E B and the pair potentials V P which are given by the analytical formulae with parameters fitted 39 to reproduce various elastic properties either known from experiment for Cu or found with firstprinciple methods for Co and Co/Cu systems. This semi-empirical model, based on the second moment tightbinding approximation, was previously used to find strain relief and shape evolution for a Co island on Cu surface.…”

mentioning

confidence: 99%

Magnetic anisotropy of vicinal (001) fcc Co films: Role of crystal splitting and structure relaxation in the step-decoration effect

Cinal

Umerski

2006

Phys. Rev. B

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The uniaxial in-plane magnetic anisotropy (UIP-MA) constant is calculated for a single step on the (001) surface of fcc Co(N ) films. The calculations are done for both an undecorated step and the step decorated with one or more, up to 7, Cu wires. Our objective is to explain the mechanisms by which the decoration decreases the UIP-MA constant, which is the effect observed experimentally for ultrathin Co films deposited on vicinal (001) Cu surfaces and can lead to reorientation of magnetization within the film plane. Theoretical calculations performed with a realistic tight-binding model show that the step decoration changes the UIP-MA constant significantly only if the splitting between the on-site energies of various d-orbitals is included for atoms located near the step edge. The local relaxation of atomic structure around the step is also shown to have a significant effect on the shift of the UIP-MA constant. The influence of these two relevant factors is analyzed further by examining individual contributions to the UIP-MA constant from atoms around the step. The magnitude of the obtained UIP-MA shift agrees well with experimental data. It is also found that an additional shift due to possible charge transfer between Cu and Co atoms is very small.

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mentioning

confidence: 99%

Magnetic anisotropy of vicinal (001) fcc Co films: Role of crystal splitting and structure relaxation in the step-decoration effect

Cinal

Umerski

2006

Phys. Rev. B

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“…A detail theoretical work by Levanov et al shows that the locations of a single Co atom in the first two atomic layers of Cu(001) provide higher energies than the locations in the deeper layers [45]. In that work, they show that the difference of energy due to the embedding in the first and second layer is larger than it is due to the embedding in the second and deeper layers.…”

Section: Factors That Determine Co Distribution In Cu(001)mentioning

confidence: 95%

“…The energetics of the Co-Cu(001) system favors Co to be located below the first layer rather than on the surface or in the first layer [45,46]. A detail theoretical work by Levanov et al shows that the locations of a single Co atom in the first two atomic layers of Cu(001) provide higher energies than the locations in the deeper layers [45].…”

Section: Factors That Determine Co Distribution In Cu(001)mentioning

confidence: 99%

Co diffusion in the near-surface region of Cu

et al. 2016

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We present our experimental and theoretical study on Co diffusion in the first few atomic layers of Cu(001). While the diffusion of Co atoms in Cu(001) is usually expected to be intense at a temperature T 800 K, in the vicinity of the surface, it is already activated at a considerably lower temperature T ∼ 650 K whereas the diffusion in the deep bulk region is still inhibited. This intense near-surface diffusion provides an accumulation of Co atoms in the first six atomic layers upon a single stage Co deposition. The details of the near-surface diffusion are studied by analyzing the distribution of the location depth of the buried single Co atoms. The depth of location of single Co atoms is deduced from scanning tunneling microscopy (STM) data. The subsurface Co atoms induce a perturbation of the electron density of states of the surface which is observable as apparent ringlike ripples in the STM images of the atomically flat Cu surface. The depth of location of the buried Co atoms is determined from the diameter of those rings. The largest amount of Co atoms is found to be in the third layer, emphasizing that the near-surface diffusion should be described by diffusion parameters different from those for bulk diffusion. A model that describes the embedding process of Co atoms into Cu(001) layers is developed. The model assumes Co atoms to diffuse via the vacancy and ring-exchange mechanisms. The energy barriers for the interlayer Co diffusion via those mechanisms are calculated using the nudged elastic band method. The model satisfactorily explains the experimental results. Our study reveals that the energy barriers for Co diffusion in the first five atomic layers of Cu(001) are lower than those in the bulk. This defines the region in which Co diffusion should be considered as a near-surface one.

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“…We model the atomic interactions with a simple Morse potential [17] and a tight-binding potential with secondmoment approximation (TB-SMA) [18]. To validate interactions, we model vacancy-assisted migration on (100)-surface of Cu and consider only first n.n.…”

Section: Symbolically-regressedmentioning

confidence: 99%

Genetic programming for multitimescale modeling

et al. 2005

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A bottleneck for multi-timescale dynamics is the computation of the potential energy surface (PES). We explore the use of genetic programming (GP) to symbolically regress a mapping of the saddle-point barriers from only a few calculated points via molecular dynamics, thereby avoiding explicit calculation of all the barriers. The GP-regressed barrier function enables use of kinetic Monte Carlo (KMC) to simulate real-time kinetics (seconds to hours) using realistic interactions. To illustrate, we apply a GP regression to vacancy-assisted migration on a surface of a binary alloy and predict the diffusion barriers within 0.1-1% error using 3% (or less) of the barriers, and discuss the significant reduction in CPU time.

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Energetics of Co adatoms on the Cu(001) surface

Cited by 130 publications

References 26 publications

Magnetic anisotropy of vicinal (001) fcc Co films: Role of crystal splitting and structure relaxation in the step-decoration effect

Magnetic anisotropy of vicinal (001) fcc Co films: Role of crystal splitting and structure relaxation in the step-decoration effect

Co diffusion in the near-surface region of Cu

Genetic programming for multitimescale modeling

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