Теоретичні дослідження впливу поверхонь поділу на інтенсивності випромінювання оптичних переходів та часів життя електронних збуджень у наносистемах германій/кремній з квантовими точками германію

In mini-review, theoretical studies of some optical properties of heteronanosystems of the second type are considered. These nanosystems are germanium/silicon with germanium quantum dots (QDs). The influence of the interfaces on the radiation intensity of optical transitions and lifetimes of electro...

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Bibliographic Details
Date:2024
Main Authors: Покутній, С. І., Громовий, Т. Ю.
Format: Article
Language:English
Published: Chuiko Institute of Surface Chemistry National Academy of Sciences of Ukraine 2024
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Online Access:https://surfacezbir.com.ua/index.php/surface/article/view/782
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Journal Title:Surface

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Surface
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Summary:In mini-review, theoretical studies of some optical properties of heteronanosystems of the second type are considered. These nanosystems are germanium/silicon with germanium quantum dots (QDs). The influence of the interfaces on the radiation intensity of optical transitions and lifetimes of electronic excitations in germanium/silicon nanosystems with germanium in the germanium/silicon nanosystems with germanium QDs is studied. Dipole-allowed optical transitions between quasi-stationary and stationary states, which occur over the spherical surface of a single germanium QD embedded in a silicon matrix, are theoretically investigated. A mechanism is proposed for a significant increase (four times) in the intensities of optical interband and intraband transitions between quasi-stationary and stationary SIE-states arising above a spherical surface of a single germanium QD placed in a silicon matrix. These optical electronic transitions occur in the real space of the silicon matrix. Such a mechanism, apparently, will apparently solve the problem of a significant increase in the radiative intensity in germanium/silicon heterostructures with germanium QDs. This will provide an opportunity to develop fundamental and applied foundations, allowing to create a new generation of effective light-emitting and photodetector devices based on germanium/silicon heterostructures with germanium quantum dots. The theoretically predicted long-lived SIE-states, apparently, will make it possible to realize high-temperature quantum Bose-gases SIE-states in the nanosystem under study.
DOI:10.15407/Surface.2024.16.043