Impact of Schwoebel Barriers on the Step-Flow Growth of a Multicomponent Crystal

Redkov, Alexey

doi:10.3390/cryst14010025

Crystals

2023

DOI: 10.3390/cryst14010025

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Impact of Schwoebel Barriers on the Step-Flow Growth of a Multicomponent Crystal

Alexey Redkov

Abstract: The step-flow and spiral growth of a multicomponent crystal are considered from vapors, taking into account the different possible Schwoebel barriers for each component within the Burton-Cabrera-Frank model. Analytic expressions for the final growth rates of such a multicomponent crystal are determined while considering the kinetic properties of all the individual components and growth conditions. Possible instabilities inherent in the presence of several components are studied, and a stability criterion for t… Show more

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2024

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Burton-Cabrera-Frank theory for the influence of off-cut direction on the growth of hcp crystals

Ju,

Xu,

Thompson

et al. 2024

Phys. Rev. B

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The precise direction of the off-cut of a vicinal crystal surface determines the azimuth (in-plane angle) of the surface steps and thus their kink density. Here we develop a Burton-Cabrera-Frank (BCF) theory for step-flow crystal growth that includes the effects of step azimuth. We focus on the basal-plane surfaces of hexagonal close-packed (hcp) and related crystal structures, for which surface steps have alternating properties that depend on azimuth. We build on a previous treatment that considered only a single-step azimuth, ϕ=0, that gives alternating steps of pure A and B type. As ϕ increases from zero, the density of kinks on the steps increases. For hcp-type crystals, in addition the structural difference between alternating steps decreases, until they become equivalent at ϕ=30∘. We consider the azimuth dependence of the step transparency, attachment, and repulsion parameters of the BCF model, including the effects of both geometrically required and thermally generated kinks. Example calculations are presented that demonstrate the overall effect of step azimuth on BCF predictions for step spacings during steady-state growth and for their dynamics during growth transients. Effects of symmetric and asymmetric step-step repulsion are discussed. Published by the American Physical Society 2024

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Burton-Cabrera-Frank theory for the influence of off-cut direction on the growth of hcp crystals

Ju,

Xu,

Thompson

et al. 2024

Phys. Rev. B

View full text Add to dashboard Cite

show abstract

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Impact of Schwoebel Barriers on the Step-Flow Growth of a Multicomponent Crystal

Cited by 1 publication

References 60 publications

Burton-Cabrera-Frank theory for the influence of off-cut direction on the growth of hcp crystals

Burton-Cabrera-Frank theory for the influence of off-cut direction on the growth of hcp crystals

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