Advancements in microwave dielectric ceramics with K20 for 5G/6G communication systems: a review

Advancements in microwave dielectric ceramics with K20 for 5G/6G communication systems: a review

The rapid advancement of 5G and 6G communication systems has driven the need for high-performance microwave dielectric ceramics, which are essential for enabling ultra-high-frequency signal transmission, device miniaturization, and thermal stability. These materials must meet stringent requirements,...

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Main Authors: He, Guo Qiang, Miao, Jin Chao, Wu, Fang Fang, Wang, Wei, Bao, Jian, Jiang, Jia Pei, Liu, Da Wei, Darwish, Moustafa Adel, Zhou, Tao, Xu, Di Ming, Xia, Song, Tan, Kar Ban, Zhou, Di
Format: Article
Language:en
Published: Royal Society of Chemistry 2025
Subjects:
Chemistry (all)
Materials Chemistry
Online Access:http://psasir.upm.edu.my/id/eprint/123307/1/123307.jpg
http://psasir.upm.edu.my/id/eprint/123307/
https://pubs.rsc.org/en/content/articlelanding/2025/tc/d5tc01366f
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Summary:The rapid advancement of 5G and 6G communication systems has driven the need for high-performance microwave dielectric ceramics, which are essential for enabling ultra-high-frequency signal transmission, device miniaturization, and thermal stability. These materials must meet stringent requirements, including ultralow dielectric loss (tan δ < 10−4), near-zero temperature coefficient of resonant frequency (τf ≈ 0 ppm °C−1), and tunable permittivity (ϵr ≈ 20), to support the growing demands of emerging technologies such as the Internet of Things (IoT), autonomous vehicles, and augmented reality (AR). This review provides a comprehensive analysis of recent progress in microwave dielectric ceramics with ϵr ≈ 20, focusing on four key material systems: MgTiO3-CaTiO3, (Ca,La)(Al,Ti)O4, LnNbO4, and Li2TiO3. We explore innovative material design strategies, including ion doping, composite modification, and advanced sintering techniques, to optimize dielectric properties such as quality factor (Q × f), temperature stability, and permittivity. Furthermore, we highlight breakthroughs in device applications, including dielectric resonator antennas (DRAs) and millimeter-wave antenna arrays, demonstrating the practical potential of these materials in 5G/6G communication systems. Future perspectives emphasize the development of high-entropy ceramics, machine-learning-guided material discovery, multifunctional and adaptive materials, and sustainable manufacturing practices. This review aims to provide a thorough understanding of the state-of-the-art in microwave dielectric ceramics, offering valuable insights for researchers and engineers working on next-generation high-frequency communication technologies.

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