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Graded Dielectric Metamaterial with Designable Permittivity Fabricated by 3D Printing

Xiaoyu Li, Denghao Ma, Xinwei Xu, Hong Wang, Hong Wang, Fei Jin, Jin Cheng, Biao Guo, Cong Liu, Hong Wang, Hong Wang

2025Advanced Functional Materials8 citationsDOIOpen Access PDF

Abstract

Abstract The increasing demand for electronic devices operating in specific frequency bands (e.g., X‐band dielectric resonator antennas) has driven the development of materials with precisely tunable permittivities. Metamaterials with artificially engineered microstructures are promising for tailoring the effective permittivity to meet application‐specific requirements. By leveraging the high precision of 3D printing, this work achieves precise control over the effective permittivity by accurately adjusting the geometric parameters of metastructures and establishes a permittivity prediction model for composite materials using effective medium theory. The application‐driven design of a graded dielectric metamaterial is demonstrated through an X‐band dielectric resonator antenna with the following significant performance improvements: a broad bandwidth (6.2 GHz) covering the entire X‐band (8–12 GHz), whereas the conventional bandwidth is only 1.7–4.2 GHz, and a gain value of 14.7 dB. This study paves the way for the development of high‐performance antennas, radio frequency components, and frequency‐selective devices with enhanced frequency adaptability and integration.

Topics & Concepts

Materials scienceMetamaterialPermittivityDielectricBandwidth (computing)Optoelectronics3D printingResonatorDielectric permittivityDielectric resonatorMetamaterial antennaInkwellTunable metamaterialsAntenna (radio)Radio frequencySplit-ring resonatorMetamaterial absorberElectronic engineeringRelative permittivity3d printedDielectric lossDielectric resonator antennaDopingComposite numberMicrostructureLow frequencyOpticsAntenna Design and AnalysisMetamaterials and Metasurfaces ApplicationsAdvanced Antenna and Metasurface Technologies