Theoretical aspects of the growth of a non-Kossel crystal from vapours: the role of advacancies

Redkov, A. V.; Кукушкин, С. А.

doi:10.1039/d1fd00083g

Cited by 4 publications

(7 citation statements)

References 70 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Previous studies have established that mechanical stress may have a significant effect on crystal growth (Cabrera and Levine, 1956). In (Redkov and Kukushkin, 2022), it was demonstrated from a thermodynamic point of view that stress affects the Frontiers in Chemistry frontiersin.org growth of multicomponent crystals in the same way by reducing the effective supersaturation according to: ξ g (σ) ξ g (0)(1 − σω kBT ), where σ is the isotropic elastic stress and ω is the volume of the crystalline cell. This reduction factor can be crucial for the epitaxial growth of semiconductor or MOF-on-MOF heterostructures.…”

Section: Impact Of Mechanical Stress and Advacanciesmentioning

confidence: 99%

“…Another important factor is the emergence and diffusion of vacancies on the crystal surface, which can recombine with adatoms and significantly affect the crystal growth or evaporation (Hirth, 1965;Pimpinelli and Villain, 1994;Sitnikov et al, 2017;Kosolobov, 2019). In (Redkov et al, 2020b;Redkov and Kukushkin, 2022), the authors extended the BCF model to the multicomponent case and accounted for the formation of additional vacancies resulting from applied stress (see Figure 2C). In this case the characteristic diffusion length, which determines the growth rate, is limited by the lowest diffusion lengths of adatoms and advacancies due to evaporation and recombination (see Figure 2C).…”

Section: Impact Of Mechanical Stress and Advacanciesmentioning

confidence: 99%

See 1 more Smart Citation

Spiral growth of multicomponent crystals: theoretical aspects

Redkov

2023

Front. Chem.

Self Cite

View full text Add to dashboard Cite

This paper presents recent advances in the theory of multicomponent crystal growth from gas or solution, focusing on the most common step-flow mechanisms: Burton-Cabrera-Frank, Chernov, and Gilmer-Ghez-Cabrera. Analytical expressions for the spiral crystal growth rate are presented, taking into account the properties of all species involved in the growth process. The paper also outlines theoretical approaches to consider these mechanisms in multicomponent systems, providing a foundation for future developments and exploration of previously unexplored effects. Some special cases are discussed, including the formation of nanoislands of pure components on the surface and their self-organization, the impact of applied mechanical stress on the growth rate, and the mechanisms of its influence on growth kinetics. The growth due to chemical reactions on the surface is also considered. Possible future directions for developing the theory are outlined. A brief overview of numerical approaches and software codes that are useful in theoretical studies of crystal growth is also given.

show abstract

Section: Impact Of Mechanical Stress and Advacanciesmentioning

confidence: 99%

Section: Impact Of Mechanical Stress and Advacanciesmentioning

confidence: 99%

Spiral growth of multicomponent crystals: theoretical aspects

Redkov

2023

Front. Chem.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Let us also introduce an additional parameter . Using approaches from [18,20,28], we write an equation for the flow of vacancies from the bulk of the crystal to the surface and a similar one for adatoms arriving at the surface from the gas phase:…”

Section: Distribution Of Adatoms and Vacancies On The Pore Surfacementioning

confidence: 99%

“…Since the process of growth of an ordinary crystal and a pore are similar, similarly to the effect of advacancies on the growth of a crystal, adatoms on the surface of a pore can affect the rate of its vacancy growth. This work is a continuation of a series of works devoted to the growth and evolution of crystals [11][12][13][25][26][27][28] and pores in single-and multicomponent systems due to various mechanisms, and its main goal is to analyze the effect of adatoms on the pore surface on its vacancy growth of the pore according to the Barton-Cabrera-Frank mechanism, and find an expression for the dependence of the pore growth rate on the applied mechanical load and the properties of the crystal.…”

Section: Introductionmentioning

confidence: 99%

Influence of Adatoms on the Vacancy Growth of Faceted Pores in a Crystal Under Mechanical Load

Redkov

Кукушкин²

2022

Mech. Solids

View full text Add to dashboard Cite

The process of growth of faceted pores in a crystal under the influence of an applied mechanical load is considered in the framework of the classical Barton-Cabrera-Frank model, taking into account the presence of adatoms on the surface of pore faces. The growth is caused by the flow of excess vacancies from the bulk of the crystal, which arise due to tensile stresses. The recombination of advacancies and adatoms on the surface of pores is taken into account, and it is shown that as a result, a flow of adatoms from steps and fissures to the terrace can occur. This additional flow contributes to the growth of pores under load and, under certain conditions, can be the predominant mechanism of mass transfer, which must be taken into account for a correct assessment of the growth rate and lifetime of the crystal under load before failure. Expressions are obtained for the dependence of the pore growth rate on the applied mechanical load, the diffusion coefficients of vacancies and adatoms, and the rate of their recombination.

show abstract

“…In [40], the classical Burton-Cabrera-Frank theory was extended to the case of multicomponent crystals growing via chemical reactions. In [41], researchers studied the effect of advacancies present on the surface on multicomponent crystal growth. The effect of fast atomic steps on the growth surface was explored in [42], revealing the importance of considering this aspect, as different components exhibit varying surface mobility.…”

Section: Introductionmentioning

confidence: 99%

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

Redkov

2023

Crystals

Self Cite

View full text Add to dashboard Cite

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 the multicomponent case is proposed. It is shown that, in certain cases, nucleation of nanoislands of pure components behind the moving steps can initiate, significantly distorting the growth process. The criterion for the occurrence of such an unstable regime is found.

show abstract

Theoretical aspects of the growth of a non-Kossel crystal from vapours: the role of advacancies

Abstract: The growth of an arbitrary multicomponent non-Kossel crystal via the Burton–Cabrera–Frank mechanism is studied, considering the effect of advacancies and their recombination with adatoms on the surface. An analysis is...

Cited by 4 publications

References 70 publications

Spiral growth of multicomponent crystals: theoretical aspects

Spiral growth of multicomponent crystals: theoretical aspects

Influence of Adatoms on the Vacancy Growth of Faceted Pores in a Crystal Under Mechanical Load

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

Contact Info

Product

Resources

About