Collective diffusion in a non-homogeneous interacting lattice gas

Badowski, Łukasz; Załuska‐Kotur, Magdalena A.; Gortel, Zbigniew W.

doi:10.1088/1742-5468/2010/03/p03008

Cited by 9 publications

(16 citation statements)

References 55 publications

(195 reference statements)

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“…with τ ± = θ(µ t ± d) = θ ± ± (χ ± /β)d + O(N −5/4 ). Intervals (20) are very narrow and concentrated around θ ± .…”

Section: B Crossover Regimesmentioning

confidence: 99%

“…One of the intriguing problems that has attracted particular attention is the presence of phase transitions and their effects on surface diffusion. Since lattice gases can be used to model such transitions, they have provided a convenient framework also in this regard [7,8,[11][12][13][14][15][16][17][18][19][20]. However, below critical temperatures ordered phases may arise due to lateral interactions, and sophisticated arguments should be applied to analyze surface diffusion [7].…”

Section: Introductionmentioning

confidence: 99%

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Many-particle surface diffusion coefficients near first-order phase transitions at low temperatures

Medved

Trník²

2012

Phys. Rev. E

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We analyze the collective surface diffusion coefficient, D c , near a first-order phase transition at which two phases coexist and the surface coverage, θ, drops from one single-phase value, θ + , to the other one, θ − . Contrary to other studies, we consider the temperatures that are sufficiently subcritical. Using the local equilibrium approximation, we obtain, both numerically and analytically, the dependence of D c on the coverage and system size, N , near such a transition. In the twophase regime, when θ ranges between θ − and θ + , the diffusion coefficient behaves as a sum of two hyperbolas, D c ≈ A/N |θ − θ − | + B/N |θ − θ + |. The steep hyperbolic increase in D c near θ ± rapidly slows down when the system gets from the two-phase regime to either of the single-phase regimes (when θ gets below θ − or above θ + ), where it approaches a finite value. The crossover behavior of D c between the two-phase and single-phase regimes is described by a rather complex formula involving the Lambert function. We consider a lattice-gas model on a triangular lattice to illustrate these general results, applying them to four specific examples of transitions exhibited by the model.

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“…with τ ± = θ(µ t ± d) = θ ± ± (χ ± /β)d + O(N −5/4 ). Intervals (20) are very narrow and concentrated around θ ± .…”

Section: B Crossover Regimesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Many-particle surface diffusion coefficients near first-order phase transitions at low temperatures

Medved

Trník²

2012

Phys. Rev. E

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“…The analytic formulas have this advantage over other methods that they give results as a function of temperature and of all other model parameters. We propose new, variational approach, that was first shown to work for many-particle diffusion process [32][33][34][35][36] . Below we show how the variational approach can be used in calculation of tracer diffusion coefficient, which describes also diffusion in the system of low density.…”

Section: Introductionmentioning

confidence: 99%

Diffusion of Ga adatoms at the surface of GaAs(001) c(4x4) $α$ and $β$ reconstructions

Mińkowski,

Załuska-Kotur

2014

Preprint

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Diffusion of Ga adatom at the As rich, low temperature c(4×4) reconstructions of GaAs(001) surface is analyzed. We use known energy landscape for the motion of Ga adatom at two different α and β surface phases to calculate diffusion tensor by means of the variational approach. Diffusion coefficient describes the character of low density adatom system motion at the surface. The resulting expressions allow to identify main paths of an adatom diffusion and to calculate an activation energy of this process. It is shown that diffusion at the α surface is slower and more anisotropic than this for the β surface.

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“…One of the relevant transport coefficients for surface diffusion is the collective (or chemical) surface diffusion coefficient, D c . It is associated with the decay of fluctuations in the adparticle density at large time and space intervals and is defined via the Fick's first law, J = −D c ∇θ, where J is the surface diffusion flux and θ is the surface coverage.Considering suitable 2D lattice gas models, computer simulation methods have been frequently applied in theoretical studies of D c (and of surface diffusion in general) with a particular interest in the presence of phase transitions and their effects on surface diffusion [3,4,5,6,7,8,9,10,11,12]. Usually, the observation that D c = Φ D CM [1] was used, where D CM is the center of mass diffusion coefficient and represents kinetic properties of D c , while Φ = N oc /( N 2 oc − N oc 2 ) is associated with thermodynamic properties of D c and is called the thermodynamic factor (N oc is the number of adsorption sites in a system occupied by adparticles and · denotes the statistical mean value).…”

mentioning

confidence: 99%

“…Considering suitable 2D lattice gas models, computer simulation methods have been frequently applied in theoretical studies of D c (and of surface diffusion in general) with a particular interest in the presence of phase transitions and their effects on surface diffusion [3,4,5,6,7,8,9,10,11,12]. Usually, the observation that D c = Φ D CM [1] was used, where D CM is the center of mass diffusion coefficient and represents kinetic properties of D c , while Φ = N oc /( N 2 oc − N oc 2 ) is associated with thermodynamic properties of D c and is called the thermodynamic factor (N oc is the number of adsorption sites in a system occupied by adparticles and • denotes the statistical mean value).…”

mentioning

confidence: 99%

Collective surface diffusion near a first-order phase transition

Medved

Trník

2011

Phys. Rev. B

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For a large class of lattice models we study the thermodynamic factor, $\Phi$, of the collective surface diffusion coefficient near a first-order phase transition between two phases at low temperatures. In a two-phase regime its dependence on the coverage, $\te$, is $\Phi \approx \te/[(\te-\te_-)(\te_+ - \te)N]$, where $N$ is the number of adsorption sites and $\te_\pm$ are the single-phase coverages at the transition. In the crossover between the two-phase and single-phase regimes $\Phi(\te)$ is shown to have a more complex behavior. The results are applied to a simple 2D lattice model.Comment: 9 pages, 4 figure

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Collective diffusion in a non-homogeneous interacting lattice gas

Cited by 9 publications

References 55 publications

Many-particle surface diffusion coefficients near first-order phase transitions at low temperatures

Many-particle surface diffusion coefficients near first-order phase transitions at low temperatures

Diffusion of Ga adatoms at the surface of GaAs(001) c(4x4) $α$ and $β$ reconstructions

Collective surface diffusion near a first-order phase transition

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