Electrical conductivity and electrical stability of Bi/Mg modified NiO ceramics for NTC thermistors

IF 0.9 4区材料科学 Q3 MATERIALS SCIENCE, CERAMICS

Processing and Application of Ceramics Pub Date : 2023-01-01 DOI:10.2298/pac2302172h

Linling Huang, Zhicheng Li, Kaifeng Li, You Zhang, Hong Zhang, S. Leng

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Abstract

Thermistors with negative temperature coefficient (NTC) of resistivity are important components for temperature sensors and actuators. High material constant (B value) of NTC thermistor, i.e. high-temperature sensitivity, is one of key focuses. Herein, Bi/Mg modified NiO based ceramics for NTC thermistors were prepared by conventional solid-state reaction method. Introduction of Bi2O3 significantly enhances the sintering ability of ceramics and reduces the sintering temperature from 1380 to 1250?C. Mg-doping (i.e. preparation of Ni1-xMgxO ceramics, where x=0, 0.02, 0.05, 0.07 and 0.1) has significant effect on room temperature resistivity (?25). Phase composition, microstructure, electrical property and electrical stability were investigated. All prepared ceramics have the phase with rock-salt structure and show typical NTC characteristics with B values higher than 5300K. The electrical stability with an optimized resistance-change rate of 1.02%after being aged at 150?C for 500 h is achieved. The electrical properties of the ceramics were analysed by combining X-ray photoelectron spectra with complex impedance spectra.

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NTC热敏电阻用Bi/Mg改性NiO陶瓷的电导率和电稳定性

电阻率为负温度系数的热敏电阻是温度传感器和执行器的重要元件。NTC热敏电阻的高材料常数(B值)，即高温灵敏度是其研究的重点之一。本文采用常规固相反应法制备了Bi/Mg改性NiO基NTC热敏电阻陶瓷。Bi2O3的加入显著提高了陶瓷的烧结能力，使烧结温度从1380℃降低到1250℃。mg掺杂(即制备Ni1-xMgxO陶瓷，其中x=0, 0.02, 0.05, 0.07和0.1)对室温电阻率(?25)有显著影响。研究了复合材料的相组成、显微组织、电学性能和电稳定性。制备的陶瓷均具有岩盐结构相，具有典型的NTC特征，B值高于5300K。在150℃时效后，电稳定性最佳，电阻变化率为1.02%。温度达到500h。结合x射线光电子能谱和复阻抗谱分析了陶瓷的电学性能。

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