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Journal Nanotechnology : the development , application - XXI Century №1 for 2022 г.
Article in number:
Optical properties of atomically thin films of the topological insulator Bi2Se3
Type of article: short message
DOI: https://doi.org/10.18127/j20700970-202102-11
UDC: 538.945
Authors:

A.V. Frolov1, A.P. Orlov2, A.G. Temiryazev3

1-4 Fryazino branch of Kotelnikov Institute of Radioengineering and Electronics of RAS (Fryazino, Russia)

Abstract:

Problem formulating. To study the transport properties of atomically thin films of topological insulators, it is very important to determine their thickness as accurately as possible, as well as the state of the surface.

Goal. To obtain atomically thin films of the topological insulator Bi2Se3 and to determine their thickness and the degree of surface degradation via their optical properties.

Result. A technique that allows one to obtain single-crystal films of large area and various thicknesses on optically transparent substrates has been developed. The dependence of the transparency depending on the number of atomic layers (Bi2Se3 quintiples) in the film is determined. The obtained exact dependence of transparency on the number of layers is in good agreement with theory. It was also possible to observe how the transparency of the films changes over time, which is associated with the degradation of its surface layers.

Practical meaning.The results obtained can be used for optical quality control of atomically thin films of quasi-two-dimensional compounds, as well as for the manufacture of various micro- and nanostructures based on them, which can bring closer to the creation of a new element base for electronic devices.

Pages: 57-61
For citation

Frolov A.V., Orlov A.P., Temiryazev A.G. Optical properties of atomically thin films of the topological insulator Bi2Se3. Nonlinear World. 2021. V. 19. № 2. 2021. P. 48-51. DOI: https://doi.org/10.18127/j20700970-202102-11 (In Russian)

References
  1. Frolov A.V. et al. Magnetoresistance of a Two-Dimensional TbTe3 Conductor in the Sliding Charge-Density Wave Regime // JETP Letters. 2018. V. 107. № 8. P. 488-492.
  2. Frolov A.V. et al. Features of pinning of a charge-density wave in quasi-two-dimensional compounds // JETP Letters. 2019. V. 109. № 3. P. 203-206.
Date of receipt: 29.04.2021
Approved after review: 17.05.2021
Accepted for publication: 27.05.2021