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Excellent permittivity-temperature stability and reliability performance of ultra-thin Ba<sub>0.97</sub>Ca<sub>0.03</sub>TiO<sub>3</sub>-based MLCCs

Xiong Huang, Lei Zhang, Pengfei Wang, Gang Jian, Jun Yang, Bo Li, Shuhui Yu, Rong Sun, Zhenxiao Fu, Xiuhua Cao

2023Journal of Asian Ceramic Societies24 citationsDOIOpen Access PDF

Abstract

High-temperature stability and reliability are in high demand for ultra-thin multilayer ceramic capacitors (MLCCs), which are ubiquitous in electronic industries. Here, two doping matrices of BaTiO3 (BT) and Ba0.97Ca0.03TiO3 (BCT) are chosen to prepare ultra-thin MLCCs, whose effects on the microstructure, nonlinear dielectric properties, temperature stability, and reliability of the capacitors were investigated. Compared with BT-based MLCCs, BCT-based MLCCs possess better core-shell structures, thus, leading to a higher Schottky barrier for inhibiting carrier migration and improving aging performance. For the 1.5 μm-thickness capacitors using the BCT doping matrix rather than BT, the temperature coefficient of capacitance reaches the X7R standard, and the breakdown field increases from 148 to 172 V/μm. Moreover, the ability to resist insulation resistance degradation has been significantly improved. This work demonstrates the great potential of using BCT as the doping matrix to prepare ultra-thin MLCCs with excellent temperature stability and reliability.

Topics & Concepts

Materials scienceCeramic capacitorDielectricDopingCapacitorCapacitanceMicrostructurePermittivityDegradation (telecommunications)Composite materialOptoelectronicsElectronic engineeringElectrical engineeringElectrodeVoltageChemistryPhysical chemistryEngineeringFerroelectric and Piezoelectric MaterialsMicrowave Dielectric Ceramics SynthesisDielectric properties of ceramics
Excellent permittivity-temperature stability and reliability performance of ultra-thin Ba<sub>0.97</sub>Ca<sub>0.03</sub>TiO<sub>3</sub>-based MLCCs | Litcius