Defect/disorder correlated modification of transport properties from hopping to tunneling processes in BaTiO3–LaFeO3 solid solution

P. Maneesha, Koyel Samantaray, Suresh Chandra Baral, R. Mittal, Mayanak K. Gupta, Somaditya Sen
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Abstract

Crystal structure, bandgap, and the changes in the charge conduction mechanisms in ceramics are interrelated, and the underlying physics unifies all these different phenomena. The experimental and theoretical evaluation of the electronic properties of the solid solution of (1 − x)BaTiO3–(x)LaFeO3 (x = 0, 0.015, 0.031, 0.062) is attempted in this work. Bandgap was observed to be tunable with La/Fe doping from 3.2 eV (x = 0) to 2.6 eV (x = 0.06), while the lattice disorder was found to increase. A theoretical assessment confirms a considerable shift of valence band maxima and conduction band minima with an introduction of additional defect states within the bandgap. Electron localization was also confirmed theoretically with doping. Such changes in the electronic properties were experimentally confirmed from dielectric/AC - conductivity/impedance spectroscopy studies. From different transportation models, hopping is a preferred mechanism in the less distorted BaTiO3. However, a large polaron tunneling process can be justified for the doped samples at lower temperatures. Only at higher temperatures, a small polaron tunneling can be justified for the doped samples. The transportation is affected by the grain boundaries as much as the grains themselves. A complete analysis using Nyquist plots reveals the competing contributions of these regions to the transportation mechanism and is correlated to the disorder/distortions in the lattice in terms of the formation of oxygen vacancies.
BaTiO3-LaFeO3 固溶体中从跳跃过程到隧道过程的输运特性的缺陷/无序相关改变
陶瓷中的晶体结构、带隙和电荷传导机制的变化是相互关联的,其基本物理学原理统一了所有这些不同的现象。本研究尝试对 (1 - x)BaTiO3-(x)LaFeO3 (x = 0, 0.015, 0.031, 0.062) 固溶体的电子特性进行实验和理论评估。观察到带隙可随 La/Fe 掺杂从 3.2 eV (x = 0) 调整到 2.6 eV (x = 0.06),同时发现晶格无序度增加。理论评估证实,随着带隙内额外缺陷态的引入,价带最大值和导带最小值发生了相当大的偏移。掺杂也从理论上证实了电子局域化。电介质/交流电导率/阻抗光谱研究也从实验上证实了电子特性的这种变化。从不同的传输模型来看,在畸变较小的 BaTiO3 中,跳变是一种优先机制。然而,在较低温度下,掺杂样品的极子隧道过程较大。只有在较高温度下,掺杂样品的极子隧道过程才较小。晶界和晶粒本身都会对传输产生影响。使用奈奎斯特图进行的全面分析揭示了这些区域对传输机制的竞争性贡献,并从氧空位的形成角度与晶格中的无序/畸变相关联。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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