﻿Effect of contact phenomena on the electrical conductivity of reduced lithium niobate

Shportenko, A. S.; Kislyuk, A. M.; Turutin, Andrei V.; Кубасов, И. В.; Malinkovich, Mikhail D.; Parkhomenko, Yu. N.

doi:10.3897/j.moem.7.4.78569

Cited by 4 publications

(1 citation statement)

References 23 publications

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“…After reduction annealing a chromium electrode was magnetron-sputtered onto the surface opposite to the polished side. Chromium forms an Ohmic contact to lithium niobate [64,65]. The crystals were attached by the chromium electrode side to a metallic substrate using Leitsilber 200 conducting silver paste.…”

Section: Methodsmentioning

confidence: 99%

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Kislyuk¹,

Ilina²,

Кубасов³

et al. 2022

MoEM

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In this work, the effect of long-term room temperature exposure on the electrical conductivity of the charged domain wall (CDWs) in nonpolar x-cut congruent lithium niobate (LiNbO3, LN) crystals has been studied. Bidomain ferroelectric structures containing head-to-head charged domain boundaries have been produced by diffusion annealing in air near the Curie temperature and by infrared annealing. The crystals have been reduction annealed in a nitrogen atmosphere for the formation of color centers and growth of the electrical conductivity. The current measured during the recording of the I-V curves of the specimens using scanning probe microscope after room temperature exposure for 91 days has been found to decrease. The effect of storage conditions on the electrical conductivity of the CDWs has been studied. Degradation of the electrical conductivity does not originate from the effect of environment on the crystal surface. It has been hypothesized that the degradation is caused by distribution of charge carriers shielding the bound charge of the CDWs.

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Section: Methodsmentioning

confidence: 99%

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Kislyuk¹,

Ilina²,

Кубасов³

et al. 2022

MoEM

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View full text Add to dashboard Cite

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Degradation of the electrical conductivity of the charged domain wall in reduced lithium niobate

Kislyuk

Ilina

Кубасов

et al. 2022

Izv. vysš. učebn. zaved., Mater. èlektron. teh.

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In the present work, we investigated the effect of prolonged exposure on the electrical conductivity of crystals with a charged domain wall (CDW) in congruent lithium niobate crystals (LiNbO3, LN) of a nonpolar x-cut. Bidomain ferroelectric structures containing charged head-to-head domain boundaries were formed in the samples using methods of diffusion annealing in the air near the Curie temperature and infrared annealing in an oxygen-free environment. Reduction annealing of crystals in a nitrogen atmosphere was carried out to form color centers and concomitant increase in conductivity. Using an atomic force microscope (AFM) we observed the effect of degradation of the current value recorded when measuring the I-V curve. The influence of storage conditions on the electrical conductivity of CDW was studied. It was found that this effect was not related to the influence of the surrounding atmosphere on the surface but was presumably related to the redistribution of charge carriers shielding the bound charge of the CDW.

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Electrophysical properties, memristive and resistive switching in charged domain walls in lithium niobate

Kislyuk,

Kubasov,

Turutin

et al. 2023

Izv. vysš. učebn. zaved., Mater. èlektron. teh.

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Charged domain walls (CDW) in ferroelectric materials are interesting from fundamental and applied points of view, since they have electrical properties different from bulk ones. At the microstructural level, CDW in ferroelectrics are two-dimensional defects that separate regions of the material with different directions of spontaneous polarization vectors. Compensation of the electric field of the bound ionic charge of the CDW by mobile carriers leads to the formation of extended narrow channels with increased conductivity in the original dielectric material. By controlling the position and angle of inclination of the CDW relative to the direction of spontaneous polarization, it is possible to change its conductivity in a wide range, which opens up broad prospects for creating memory devices, including for neuromorphic systems. The review presents the current state of research in the field of formation and application of CDW formed in single crystals of uniaxial ferroelectric lithium niobate (LiNbO3, LN) as resistive and memristive switching devices. The main methods for forming CDW in single crystals and thin films of LN are considered, and modern data on the electrophysical properties and methods for controlling the electrical conductivity of CDW are presented. The prospects for using CDW in memory devices with resistive and memristive switching are discussed.

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Effect of contact phenomena on the electrical conductivity of reduced lithium niobate

Cited by 4 publications

References 23 publications

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Degradation of the electrical conductivity of the charged domain wall in reduced lithium niobate

Electrophysical properties, memristive and resistive switching in charged domain walls in lithium niobate

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﻿Effect of contact phenomena on the electrical conductivity of reduced lithium niobate

Cited by 4 publications

References 23 publications

﻿Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

﻿Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Degradation of the electrical conductivity of the charged domain wall in reduced lithium niobate

Electrophysical properties, memristive and resistive switching in charged domain walls in lithium niobate

Contact Info

Product

Resources

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Effect of contact phenomena on the electrical conductivity of reduced lithium niobate

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals

Degradation of the electrical conductivity of charged domain walls in reduced lithium niobate crystals