Quantization of Electrical Conductance in Layered Zr/ZrO2/Au Memristive Structures

IF 1.1 4区 化学 Q4 CHEMISTRY, PHYSICAL
A. S. Vokhmintsev, I. A. Petrenyov, R. V. Kamalov, M. S. Karabanalov, I. A. Weinstein,  A. A. Rempel
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引用次数: 0

Abstract

Anodic zirconia nanotubes are a promising functional medium for the formation of non-volatile resistive memory cells. The current–voltage characteristics in the region of low conductance of the fabricated Zr/ZrO2/Au memristive structures were studied in this work. For the first time, an analysis was made of the reversible mechanisms of formation and destruction of single quantum conductors based on oxygen vacancies, which participate in processes of multiple resistive switching between low- and high-resistance states in the nanotubular dioxide layer. An equivalent electrical circuit of a parallel resistor connection was proposed and discussed to describe the observed memristive behavior of the studied layered structures.

Abstract Image

Abstract Image

层状 Zr/ZrO2/Au 膜结构中电导的定量化
摘要阳极氧化锆纳米管是一种很有前途的功能介质,可用于形成非易失性电阻记忆电池。这项工作研究了所制备的 Zr/ZrO2/Au 记忆结构在低电导区域的电流-电压特性。首次分析了基于氧空位的单量子导体形成和破坏的可逆机制,这些量子导体参与了纳米管二氧化物层中低电阻态和高电阻态之间的多重电阻切换过程。提出并讨论了并联电阻器连接的等效电路,以描述所观察到的层状结构的记忆行为。
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来源期刊
Doklady Physical Chemistry
Doklady Physical Chemistry 化学-物理化学
CiteScore
1.50
自引率
0.00%
发文量
9
审稿时长
6-12 weeks
期刊介绍: Doklady Physical Chemistry is a monthly journal containing English translations of current Russian research in physical chemistry from the Physical Chemistry sections of the Doklady Akademii Nauk (Proceedings of the Russian Academy of Sciences). The journal publishes the most significant new research in physical chemistry being done in Russia, thus ensuring its scientific priority. Doklady Physical Chemistry presents short preliminary accounts of the application of the state-of-the-art physical chemistry ideas and methods to the study of organic and inorganic compounds and macromolecules; polymeric, inorganic and composite materials as well as corresponding processes. The journal is intended for scientists in all fields of chemistry and in interdisciplinary sciences.
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