Kinetics of epitaxial formation of nanostructures by Frank-van der Merwe, Volmer-Weber and Stranski-Krastanow growth modes K. A. Lozovoy, A. G. Korotaev, A. P. Kokhanenko [et al.]
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ArticleContent type: Текст Media type: электронный Subject(s): двумерные материалы | квантовые ямы | квантовые точки | наноэлектроника | нанофотоника | оптоэлектронные устройстваGenre/Form: статьи в журналах Online resources: Click here to access online
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Surface and coatings technology Vol. 384. P. 125289 (1-5)Abstract: Nowadays, two-dimensional crystals (2D materials) and structures with quantum dots (0D materials) are considered
as one of the most promising materials for electronics and photonics of the next generation. The basic
method of synthesis of heterostructures with 2D and 0D structures is their self-induced formation during the
molecular beam epitaxy. Three epitaxial growth modes are distinguished: Frank–van der Merwe, Volmer–Weber,
and Stranski–Krastanow, that allow one to obtain multi-layered structures with 2D materials, quantum wells and
quantum dots. In this work generalized kinetic model of epitaxial growth of nanostructures by all three mechanisms
is presented. Comparison of various growth modes is conducted and their peculiarities are pointed out.
Ways to control the properties of obtained 2D and 0D nanostructures are proposed with the help of the established
model.
Библиогр.: 34 назв.
Nowadays, two-dimensional crystals (2D materials) and structures with quantum dots (0D materials) are considered
as one of the most promising materials for electronics and photonics of the next generation. The basic
method of synthesis of heterostructures with 2D and 0D structures is their self-induced formation during the
molecular beam epitaxy. Three epitaxial growth modes are distinguished: Frank–van der Merwe, Volmer–Weber,
and Stranski–Krastanow, that allow one to obtain multi-layered structures with 2D materials, quantum wells and
quantum dots. In this work generalized kinetic model of epitaxial growth of nanostructures by all three mechanisms
is presented. Comparison of various growth modes is conducted and their peculiarities are pointed out.
Ways to control the properties of obtained 2D and 0D nanostructures are proposed with the help of the established
model.
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