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Engineering Individual Oxygen Vacancies: Domain-Wall Conductivity and Controllable Topological Solitons

Hemaprabha Elangovan, Maya Barzilay, Jiawei Huang, Shi Liu, Shai Cohen, Yachin Ivry

2021ACS Nano21 citationsDOIOpen Access PDF

Abstract

at domain walls of seminal titanate perovskite ferroics. The atomic-scale electric-field, charge, dipole-moment, and strain distribution around these vacancies were characterized by combining advanced transmission electron microscopy and first-principle methodologies. The engineered vacancies were used to form quasi-linear quadrupole topological defects. Significant intraband states were found in the unit cell of the engineered vacancies, proposing a meaningful domain-wall conductivity for miniaturized data-storage applications. Reduction of the Ti ion as well as enhanced charging and electric-field concentration were demonstrated near the vacancy. A 3-5% tensile strain was observed at the immediate surrounding unit cells of the vacancies. Engineering individual oxygen vacancies and topological solitons thus offers a platform for predetermining both atomic-scale and global functional properties of device miniaturization in metal oxides.

Topics & Concepts

Materials scienceTopological defectTopology (electrical circuits)NanotechnologyElectric fieldAtomic unitsStrain engineeringDipoleCondensed matter physicsOxygenMiniaturizationChemical physicsOptoelectronicsChemistryPhysicsElectrical engineeringEngineeringQuantum mechanicsSiliconOrganic chemistryElectronic and Structural Properties of OxidesFerroelectric and Piezoelectric MaterialsMultiferroics and related materials
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