3-D Printing and Gallium-Based Liquid Metal Technologies for Microwave and Millimeter-Wave Components

被引：0

作者：

Aubert, Herve ^{[1
,2
]}

Henry, Dominique ^{[3
]}

Pons, Patrick ^{[2
]}

机构：

[1] Toulouse Univ, Dept Elect & Elect Engn, Toulouse, France

[2] CNRS, Lab Anal & Architecture Syst LAAS, MINC Team, F-31000 Toulouse, France

[3] Ovalie Innovat, F-32000 Auch, France

来源：

PROCEEDINGS OF THE IEEE | 2024年 / 112卷 / 08期

关键词：

Printing; Millimeter wave technology; Metals; Microwave technology; Microwave filters; Microwave circuits; Liquids; 3-D printing technologies; 4-D printing; additive manufacturing; antennas; eutectic gallium indium alloy (EGaIn); filters; Galinstan; gallium-based (Ga-based) alloy; liquid metal (LM); microwaves; millimeter-waves; wireless sensors; RECONFIGURABLE PATCH ANTENNA; LOW-COST; GUIDE; FREQUENCY; ALLOY; ARRAY;

D O I：

10.1109/JPROC.2024.3459072

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

This article presents an overview of 3-D-printed microwave and millimeter-wave components integrating gallium-based (Ga-based) liquid metal (LM). The LM is considered here as a fourth degree of freedom for the design of 3-D-printed antennas, filters, and wireless sensors. The 3-D printing combined with LM technology can be considered as a 4-D printing technology. It can benefit from the advantages offered by 3-D printing technologies (low cost and fast manufacturing) and LM at room temperature (flexibility and reconfigurability). To date, in microwave and millimeter-wave applications, 4-D printing technology is mainly used to achieve the metallization and/or reconfigurability and/or mechanical flexibility of high-frequency 3-D-printed components.

引用

页码：1051 / 1064

页数：14

共 50 条

[41] 3-D Millimeter-Wave Imaging for Sparse MIMO Array With Range Migration and l2-Norm-Reinforced Sparse Bayesian Learning
Tu, Hao
Yu, Libin
Wang, Zhaolong
Huang, Wen
Sang, Lei
IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2025, 74
[42] 3D Printing Technologies for Fabrication of Magnetic Materials Based on Metal-Polymer Composites: A Review
Mazeeva, Alina
Masaylo, Dmitriy
Razumov, Nikolay
Konov, Gleb
Popovich, Anatoliy
MATERIALS, 2023, 16 (21)
[43] Low-Profile Directive Millimeter-Wave Antennas Using Free-Formed Three-Dimensional (3-D) Electromagnetic Bandgap Structures
Lee, Yoonjae
Lu, Xuesong
Hao, Yang
Yang, Shoufeng
Evans, Julian R. G.
Parini, Clive G.
IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, 2009, 57 (10) : 2893 - 2903
[44] High-Contrast, Low-Cost, 3-D Visualization of Skin Cancer Using Ultra-High-Resolution Millimeter-Wave Imaging
Mirbeik-Sabzevari, Amir
Oppelaar, Erin
Ashinoff, Robin
Tavassolian, Negar
IEEE TRANSACTIONS ON MEDICAL IMAGING, 2019, 38 (09) : 2188 - 2197
[45] Experimental Demonstration of Millimeter-Wave Self-Bending Over-Obstacle Focused Beam Using Single Phase-Modulated 3-D Printed Dielectric Plate Structure
Shao, Wenyi
Yang, Bo
Shinohara, Naoki
IEEE ANTENNAS AND WIRELESS PROPAGATION LETTERS, 2024, 23 (03): : 1090 - 1094
[46] Incremental solidification (toward 3D-printing) of metal powders by transistor-based microwave applicator
Shelef, Amir
Jerby, Eli
MATERIALS & DESIGN, 2020, 185
[47] Sub-Millimeter-Wave Imaging Array at 500 GHz Based on 3-D Electromagnetic-Bandgap Material
Ederra, Inigo
Gonzalo, Ramon
Alderman, Byron E. J.
Huggard, Peter G.
de Hon, Bastiaan P.
van Beurden, Martijn C.
Murk, Axel
Marchand, Laurent
de Maagt, Peter
IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 2008, 56 (11) : 2556 - 2565
[48] Feasibility Study on 3-D Printing of Metallic Structural Materials with Robotized Laser-Based Metal Additive Manufacturing
Yaoyu Ding
Radovan Kovacevic
JOM, 2016, 68 : 1774 - 1779
[49] k- and Doppler Velocity Decomposition-Based Range Points' Migration for 3-D Localization With Millimeter Wave Radar
Ando, Takeru
Kidera, Shouhei
IEEE SENSORS JOURNAL, 2022, 22 (23) : 22850 - 22864
[50] Droplet-Based Additive Manufacturing of Hard Metal Components by Thermoplastic 3D Printing (T3DP)
Scheithauer, U.
Poetschke, J.
Weingarten, S.
Schwarzer, E.
Vornberger, A.
Moritz, T.
Michaelis, A.
JOURNAL OF CERAMIC SCIENCE AND TECHNOLOGY, 2017, 8 (01): : 155 - 159

← 1 2 3 4 5 →