Multi-physics and trans-physics metamaterials

超材料 灵活性(工程) 微波食品加热 光学(聚焦) 计算机科学 变换光学 物理 钥匙(锁) 纳米技术 光子超材料 工程物理 信号(编程语言) 信号处理
作者
Han Wei Tian,Qian Zhu,Yu Hua Xiao,Chao Song,Ya Li Zhao,Z F Zhang,Xin Ge Zhang,Tie Jun Cui,Wei Jiang
出处
期刊:Applied physics reviews [American Institute of Physics]
卷期号:13 (3)
标识
DOI:10.1063/5.0315579
摘要

Metamaterials are artificially engineered structures with high designability and flexibility and can exhibit unique properties that surpass the natural materials. Initially demonstrated in the microwave regime, the metamaterials have subsequently facilitated advancements across diverse physical domains, encompassing optics, acoustics, and beyond. More importantly, the metamaterials offer unprecedented opportunities to manipulate the behaviors of multiple physical waves simultaneously, as well as to manipulate one physical wave by using the others, giving rise to the rapid development of multi-physics and trans-physics metamaterials. Here, we focus on the recent advancements in both multi-physics and trans-physics metamaterials, from basic working mechanisms to realized functions and emerging applications. For multi-physics metamaterials, we illustrate the progress in acoustic-microwave dual-physics metamaterials, light-microwave dual-physics metamaterials, and several triple-physics metamaterials to elucidate how a single metamaterial structure can simultaneously manipulate two or more types of physical waves. For trans-physics metamaterials, we highlight four representative categories: light-controlled microwave metamaterials, light-controlled optical metamaterials, light-controlled acoustic metamaterials, and acoustic-controlled microwave metamaterials, demonstrating how the metamaterials can be utilized to achieve trans-physics wave manipulations and hybrid signal conversion and information transmission. Finally, we conclude by identifying key challenges, enabling technologies and future opportunities of multi-physics and trans-physics metamaterials.
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