Simulation of a Single-Electron Device Based on Endohedral Fullerene (KI)@C180

Istlyaup, A.S.; Duisenova, A.; Myasnikova, L.; Sergeyev, D.; Попов, А. И.

doi:10.3390/inorganics11020055

Inorganics

2023

DOI: 10.3390/inorganics11020055

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Simulation of a Single-Electron Device Based on Endohedral Fullerene (KI)@C180

A.S. Istlyaup

A. Duisenova

L. Myasnikova

et al.

Abstract: The progress of modern electronics largely depends on the possible emergence of previously unknown materials in electronic technology. The search for and combination of new materials with extraordinary properties used for the production of new small-sized electronic devices and the improvement of the properties of existing materials due to improved technology for their manufacture and processing, in general, will determine the progress of highly promising electronics. In order to solve the problematic tasks of… Show more

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2024

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Cited by 2 publications

References 44 publications

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Computer simulation of the density of states and band structure of NaF nanotubes

Istlyaup,

Myasnikova,

Sergeyev

et al. 2024

Low Temperature Physics

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Modern solid-state physics increasingly focuses on the study of nanomaterials and the development of nanotechnologies. Various theoretical methods and research technologies are actively used to elucidate the significance of experimental results related to the study of solid-state defects. Progress in this field is likely associated with advancements in computer technologies and the development of modern quantum-chemical packages. The obtained spectra reveal a certain number of energy levels in the energy range from –30 to 20 eV. We determine the band structure, density of states, and total energy of NaF nanotubes with parameters (m, n), where m = 4, 5, 6, 8, and n = 1, 2, 3. The characteristics modeling is conducted using the Atomistix ToolKit software package and Virtual NanoLab program. This work presents the results of computer modeling of the density of states and total energy of NaF nanotubes within the framework of density functional theory. The obtained results allow classifying the tubular structures of NaF as quantum dots and contribute to further research into alkali metal halide crystals in nanostructures.

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Computer simulation of the density of states and band structure of NaF nanotubes

Istlyaup,

Myasnikova,

Sergeyev

et al. 2024

Low Temperature Physics

View full text Add to dashboard Cite

show abstract

Computer simulation of the electrical properties of carbon nanotubes encapsulated with alkali metal iodide crystals

Istlyaup,

Myasnikova,

Bezrukovs

et al. 2024

Low Temperature Physics

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The progress of modern electronics largely depends on the discovery and use of new materials with unique properties. One of such promising materials is carbon nanotubes. Their outstanding mechanical, thermal, and electrical properties open up new possibilities for creating small-sized electronic devices and improving the characteristics of existing materials by improving their manufacturing and processing technologies. One of the unique features of carbon nanotubes is their ability to encapsulate other atoms or molecules within their structure. This property can be used to create nanocontainers capable of protecting and transporting active substances or to change the electronic properties of nanotubes depending on the encapsulated substance. In this work, crystals of alkali metal iodides MI were encapsulated in carbon nanotubes with different structures and characteristics. The results obtained in terms of energy and density spectra of the state indicate the characteristics of conductivity due to an increase in energy and high peaks in the Fermi level. Thus, carbon nanotubes represent an important material for future developments in the field of nanoelectronics and nanotechnology.

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Simulation of a Single-Electron Device Based on Endohedral Fullerene (KI)@C180

Cited by 2 publications

References 44 publications

Computer simulation of the density of states and band structure of NaF nanotubes

Computer simulation of the density of states and band structure of NaF nanotubes

Computer simulation of the electrical properties of carbon nanotubes encapsulated with alkali metal iodide crystals

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