Classical nucleation theory approach to two-step nucleation of crystals

•Extension of classical nucleation theory (CNT) to two-step nucleation (2SN).•CNT description of 2SN thermodynamics by means of the composite-cluster model.•CNT-based thermodynamic criterion for occurrence of 2SN of crystals.•Master equation of 2SN kinetics and general expression for 2SN rate of cry...

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Published inJournal of crystal growth Vol. 530; p. 125300
Main Author Kashchiev, Dimo
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 15.01.2020
Elsevier BV
Subjects
A1. Ostwald’s step rule
A1. Two-step nucleation kinetics
A1. Two-step nucleation rate
A1. Two-step nucleation thermodynamics
Crystals
Kinetics
Metastable phases
Nucleation
A1. Two-step nucleation rate
A1. Two-step nucleation thermodynamics
A1. Ostwald’s step rule
A1. Two-step nucleation kinetics
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Abstract •Extension of classical nucleation theory (CNT) to two-step nucleation (2SN).•CNT description of 2SN thermodynamics by means of the composite-cluster model.•CNT-based thermodynamic criterion for occurrence of 2SN of crystals.•Master equation of 2SN kinetics and general expression for 2SN rate of crystals. Crystals may not always nucleate directly in the supersaturated old phase, but rather in a precursory metastable phase. This so-called two-step (2S) nucleation of crystals has recently emerged as a subject of considerable research interest. In the present paper, the composite-cluster model of the classical nucleation theory (CNT) is used to gain insight into the thermodynamics and kinetics of 2S nucleation. The standard CNT approach is applied to examine the process and it is shown that CNT is able to provide a general conceptual and mathematical framework for describing 2S nucleation. Within the caveats of CNT, a simple thermodynamic criterion is proposed for the conditions under which 2S nucleation is strongly favored and the master equation of 2S nucleation kinetics is formulated. Finally, general expressions for the 2S nucleation rates of crystals in the old phase and in the precursory metastable phase are derived.
AbstractList Crystals may not always nucleate directly in the supersaturated old phase, but rather in a precursory metastable phase. This so-called two-step (2S) nucleation of crystals has recently emerged as a subject of considerable research interest. In the present paper, the composite-cluster model of the classical nucleation theory (CNT) is used to gain insight into the thermodynamics and kinetics of 2S nucleation. The standard CNT approach is applied to examine the process and it is shown that CNT is able to provide a general conceptual and mathematical framework for describing 2S nucleation. Within the caveats of CNT, a simple thermodynamic criterion is proposed for the conditions under which 2S nucleation is strongly favored and the master equation of 2S nucleation kinetics is formulated. Finally, general expressions for the 2S nucleation rates of crystals in the old phase and in the precursory metastable phase are derived.
•Extension of classical nucleation theory (CNT) to two-step nucleation (2SN).•CNT description of 2SN thermodynamics by means of the composite-cluster model.•CNT-based thermodynamic criterion for occurrence of 2SN of crystals.•Master equation of 2SN kinetics and general expression for 2SN rate of crystals. Crystals may not always nucleate directly in the supersaturated old phase, but rather in a precursory metastable phase. This so-called two-step (2S) nucleation of crystals has recently emerged as a subject of considerable research interest. In the present paper, the composite-cluster model of the classical nucleation theory (CNT) is used to gain insight into the thermodynamics and kinetics of 2S nucleation. The standard CNT approach is applied to examine the process and it is shown that CNT is able to provide a general conceptual and mathematical framework for describing 2S nucleation. Within the caveats of CNT, a simple thermodynamic criterion is proposed for the conditions under which 2S nucleation is strongly favored and the master equation of 2S nucleation kinetics is formulated. Finally, general expressions for the 2S nucleation rates of crystals in the old phase and in the precursory metastable phase are derived.
ArticleNumber 125300
Author Kashchiev, Dimo
Author_xml – sequence: 1
  givenname: Dimo
  surname: Kashchiev
  fullname: Kashchiev, Dimo
  email: kash@ipc.bas.bg
  organization: Institute of Physical Chemistry, Bulgarian Academy of Sciences, ul. Acad. G. Bonchev 11, Sofia 1113, Bulgaria
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Snippet •Extension of classical nucleation theory (CNT) to two-step nucleation (2SN).•CNT description of 2SN thermodynamics by means of the composite-cluster...
Crystals may not always nucleate directly in the supersaturated old phase, but rather in a precursory metastable phase. This so-called two-step (2S) nucleation...
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SubjectTerms A1. Ostwald’s step rule
A1. Two-step nucleation kinetics
A1. Two-step nucleation rate
A1. Two-step nucleation thermodynamics
Crystals
Kinetics
Metastable phases
Nucleation
Title Classical nucleation theory approach to two-step nucleation of crystals
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