Journal of Radio Electronics. eISSN 1684-1719. 2024. №11

Full text in Russian (pdf)

DOI: https://doi.org/10.30898/1684-1719.2024.11.9

Spectral response
of a single ZnO nanowire

Maria Evstafieva¹, Alexander Zotov¹, Artem Irzhak^1,2, Victor Koledov²,
Andrey Orlov², Aleksei Prokunin², Svetlana von Gratowski², Peter Lega²,
Irek Musabirov³, Denis A. Vinnik⁴, Vitaly I. Korepanov¹

¹Institute of Microelectronics Technology and High-Purity Materials RAS
142432, Chernogolovka, Akademika Osipyan St., 6

² Kotelnikov IRE RAS
125009, Russia, Moscow, Mokhovaya str., 11, b.7

³ Institute of Metals Superplasticity Problems RAS
450001, Ufa, Stepan Khalturin str., 39

⁴ Moscow Institute of Physics and Technology (national research university)
141701, Moscow region, Dolgoprudny, Institutskiy pereulok, 9.

The paper was received November 17 2024.

Abstract. Miniaturization of devices based on one-dimensional semiconductor nanocrystals is of high importance for high-frequency applications, photonics, and various sensors. Zinc oxide, one of the materials actively studied for such purposes, can be obtained by several technologies. Among them, chemical vapor deposition is distinguished by a low concentration of defects in the resulting structures. The aim of this work was to fabricate a test device on a single ZnO nanocrystal by means of nanomanipulation and to study its spectral response in the range from near-IR to UV. Since one of the promising applications of ZnO is UV sensors, the task was to test the selectivity of the response to the wavelength range below 400 nm.

Key words: nanomanipulation, ZnO, semiconductors, sensors.

Financing: Ministry of Education and Science of the Russian Federation within the agreement 075-15-2024-560 from 25.04.2024

Corresponding author: Korepanov Vitaly, korepanov@iprm.ru

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For citation:

Evstafieva M.V., Zotov A.V., Irzhak A.V., Koledov V.V., Orlov A.P., Prokunin A.V., von Gratowski S.V., Lega P.V., Musabirov I.I., Vinnik D.A., Korepanov V.I. Spectral response of a single ZnO nanowire. // Journal of Radio Electronics. – 2024. – №. 11. https://doi.org/10.30898/1684-1719.2024.11.9 (In Russian)