Properties of Interface Structures Based on Oxidized Lead Selenide

N. A Tulina; Тулина Н. А; A. N Rossolenko; Россоленко А. Н; I. M Shmytko; Шмытько И. М; I. Y Borisenko; Борисенко И. Ю; D. N Borisenko; Борисенко Д. Н; N. N Kolesnikov; Колесников Н. Н

doi:10.7868/S3034573125050118

Properties of Interface Structures Based on Oxidized Lead Selenide

Authors: Tulina N.A¹, Rossolenko A.N¹, Shmytko I.M¹, Borisenko I.Y², Borisenko D.N¹, Kolesnikov N.N¹
Affiliations:
1. Osippan Institute of Solid State Physics RAS
2. Institute of Problems of Microelectronics Technology and Especially Pure Materials RAS
Issue: No 5 (2025)
Pages: 92-98
Section: Articles
URL: https://journals.rcsi.science/1028-0960/article/view/356816
DOI: https://doi.org/10.7868/S3034573125050118
ID: 356816

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Abstract

In this work, single-phase monocrystalline and thin-film samples of lead selenide were synthesized. Methods have been developed for the creation of surface oxidized lead selenide with a conductivity different from the base PbSe. Using oxidized lead selenide as an interface, Ag/Pb₃OSeO₃/PbSe heterostructures were made, demonstrating stable memristive characteristics. The obtained heterojunctions were investigated for the detection of resistive switching, the volt-ampere characteristics and the temperature dependence of the resistance of the structures were measured. By changing the external parameters: frequency, magnitude of the electric field voltage applied to the heterocontact, different metastable states are realized. Dynamic effects were studied, and the transition times from one metastable state to another were determined. Single crystal-based memristors were more stable than film structures, reproducible characteristics in single crystal-based memristors were observed for several months.

Keywords

interface of media, heterophase materials, semiconductors, metals, films, resistive switching, memristor, oxygen doping

References

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Properties of Interface Structures Based on Oxidized Lead Selenide

Full Text

Abstract

Keywords

About the authors

References

Supplementary files