Diffusion rates of Cu adatoms on Cu(111) in the presence of an adisland nucleated at fcc or hcp sites

Marinica, Mihai-Cosmin; Barreteau, Cyrille; Spanjaard, D.; Desjonquères, M.C.

doi:10.1103/physrevb.72.115402

Cited by 44 publications

(70 citation statements)

References 66 publications

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“…For the 3p elements an exponent of 0.507 and a Meyer-Neldel energy of 0.014 eV, as well as a reference frequency ν 0 of 0.01 THz, is found. These parameters differ strongly from what has been found for the 4d and 5d TM impurities [61], and appear to be closer to other analyses [100,101]. However, an alternate Meyer-Neldel analysis of the computed log(D 0 ) versus H mig,2 values does not yield a significant correlation because the D 0 are similar for all impurity elements considered.…”

Section: Diffusivitiescontrasting

confidence: 48%

First-principles analysis of solute diffusion in dilute bcc Fe- X alloys

2017

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The diffusivities of substitutional impurity elements in iron have been computed with ab inito electronic density functional techniques, using exchange-correlation functional PW91. Excess entropies and the attempt frequency for a jump were determined by calculating phonon frequencies in the harmonic approximation. The influence of the degree of spontaneous magnetization on diffusivity is taken into account by means of the Girifalco model. The activation energy for diffusion has been determined by computing the vacancy formation energy, impurity-vacancy binding energies, migration barrier energies, and the effective energy associated with correlation of vacancy-mediated jump. For each type of impurity atom these contributions have been evaluated and analyzed up to and including the fifth nearest-neighbor shell of the impurity atom. It is found that impurities that have a low migration energy tend to have high effective energy associated with vacancy migration correlation, and vice versa, so that the total diffusion activation energies for all impurities are surprisingly close to each other. The strong effect of vacancy migration correlation is found to be associated with the high migration energy for iron self-diffusion, so that movement of vacancies through the iron bulk is in all cases, except cobalt, the limiting factor for impurity diffusion. The diffusivities calculated with the PW91 functional show good agreement with most of the experimental data for a wide range of elements.

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Section: Diffusivitiescontrasting

confidence: 48%

First-principles analysis of solute diffusion in dilute bcc Fe- X alloys

2017

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“…Kurpick et al [8] and Marinica et al [4] have calculated the prefactors of a number of hopping mechanisms for self-diffusion of Ir and Cu clusters, and found that for all hopping mechanisms the prefactors were of the same order of magnitude as in a single atom diffusion. There is no hint of the large prefactor values found in experiments.…”

Section: Resultsmentioning

confidence: 97%

“…The phonon density of states (SðnÞ) of the clusters are obtained in the constant volume and constant energy ensemble at T ¼ 100 K, calculated for clusters by Fourier transform of the velocity auto-correlation function [4,12]:…”

Section: Simulation Approachmentioning

confidence: 99%

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Comparative study of compact hexagonal cluster self-diffusion on Cu(111) and Pt(111)

Yang

2008

Applied Surface Science

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“…The embedded atomic method (EAM) model was employed to describe the interaction potential between Cu atoms. The original parameters of Cu EAM were derived from Mishin et al [29], which have been proved to successfully model Cu crystal and cluster [30][31][32]. The Verlet method was used to integrate the classical equation of motion with a time-step of 2.5 fs.…”

Section: Simulation Detailsmentioning

confidence: 99%

Transitions and Geometric Evolution of Cu309 Nanocluster during Slow Cooling Process

Zhao

Wan

et al. 2018

Crystals

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Abstract:Since the nucleation and growth of clusters is usually a non-equilibrium condensation process, a distribution of structural isomers for a given cluster size may be encountered even under the same conditions. In this work, molecular dynamics simulations are performed on sets of molten clusters of Cu 309 to study their structures at low temperatures while controlling the cooling rate. Several different final structures including perfect icosahedra (ICO), imperfect Mark' decahedra (MDEC) and imperfect FCC truncated octahedra (TOCT) are obtained even at the same cooling rate. It is calculated that the most favorable structure is icosahedra, which becomes more and more favorable as the cooling rate is slowed. To better understand the process of crystallization, several techniques, including potential-temperature curves, common neighbor analysis (CNA) and radial distribution function (RDF), are used to analyze and study the structural transition. Results show that different structures are obtained under identical conditions due to the stochastic nature of nucleation and relatively small energy difference between isomers. The process of geometrical evolution for icosahedra is given by comparing and analyzing the time evolution of the root-mean-square deviation (RMSD) of atoms located in every shell.

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Diffusion rates of Cu adatoms on Cu(111) in the presence of an adisland nucleated at fcc or hcp sites

Cited by 44 publications

References 66 publications

First-principles analysis of solute diffusion in dilute bcc Fe- X alloys

First-principles analysis of solute diffusion in dilute bcc Fe- X alloys

Comparative study of compact hexagonal cluster self-diffusion on Cu(111) and Pt(111)

Transitions and Geometric Evolution of Cu309 Nanocluster during Slow Cooling Process

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