SrTiO3-ZnO陶瓷的合成与烧结:ZnO含量对微观结构和介电性能的影响

M. Kashif, Maki Habib, M. A. Rafiq, Moaz Waqar, M. A. Hussain, Ayesha Iqbal, Mehboobhusain Abbasi, Shaukat Saeed
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引用次数: 0

摘要

将现代钙钛矿和纤锌矿结构半导体材料结合的经典体系用于模拟功能新型电子器件的内部结构。结构-性能关系对金属氧化物基功能陶瓷的性能有重要影响。研究了固态反应法制备的SrTiO3-xZnO(0≤x≤10 wt%)陶瓷的结构和电学性能。x射线衍射(XRD)和扫描电子显微镜(sem)分别证实了Pm3′m空间群的单相立方结构的存在,并导致其密度增大。在300 ~ 500℃的温度范围内,在100 Hz ~ 1 MHz的频率范围内进行复阻抗谱(CIS),研究晶粒体积和晶界对阻抗行为的贡献。晶粒边界决定了样品的总电阻,ZnO的加入使SrTiO3的总电导率提高。温度升高会降低两种元件的电阻,在较高的频率下,证实了样品的负温度系数电阻(NTCR)行为。升高的温度降低了晶粒体积和晶界的弛豫,从而预测了跳变传导机制。研究结果将有助于SrTiO3在传感器、致动器和能源器件等实际应用中的微观结构设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Synthesis and sintering of SrTiO3–ZnO ceramics: Role of ZnO content on microstructure and dielectric properties
The classical system of combining modern perovskite and wurtzite structure semiconductor materials is used to model the internal structure for the applications of functional novel electronic devices. The structure-property relation has a significant impact on the properties of metal oxides-based functional ceramics. The structural and electrical properties of SrTiO3-xZnO (0 ≤x≤ 10 wt%) ceramics produced via solid-state reaction (SSR) were thoroughly examined. X-ray diffraction (XRD) and scanning electron microscopy confirmed the presence of a mono-phase cubic structure with Pm3̅m space group and resulted in increased density respectively. Complex impedance spectroscopy (CIS) was carried out from 300 to 500 °C temperature within the frequency range of 100 Hz to 1 MHz to study the contribution of grain bulk and grain boundary for impedance behavior. Grain boundaries dominated the overall resistance of the samples and the addition of ZnO in SrTiO3 caused an increase in the overall conductivity. Increasing temperature decreases the resistance of both components, and at higher frequencies that confirms the negative temperature coefficient resistance (NTCR) behavior of the samples. Increasing temperature decreases the relaxation of grain bulk and grain boundary thus predicting the hopping conduction mechanism. The results will be helpful to engineer the microstructure of SrTiO3 based on practical applications such as sensors, actuators, and energy devices.
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