Flexible Metamaterial Electronics
发布时间:2024-03-15
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- 论文类型:
- 期刊论文
- 第一作者:
- Shan Jiang
- 通讯作者:
- YongAn Huang
- 合写作者:
- Xuejun Liu,Jianpeng Liu,Dong Ye,Yongqing Duan,Kan Li,Zhouping Yin
- 发表刊物:
- Advanced Materials
- 收录刊物:
- SCI
- 所属单位:
- State Key Laboratory of Digital Manufacturing Equipment and Technology
- 项目来源:
- National Natural Science Foundation of China (Grant Nos. 51925503 and 52105575), the China Postdoct
- 卷号:
- 34
- 期号:
- 52
- DOI码:
- 10.1002/adma.202200070
- 发表时间:
- 2022-12-28
- 摘要:
- Over the last decade, extensive efforts have been made on utilizing advanced materials and structures to improve the properties and functionalities of flexible electronics. While the conventional ways are approaching their natural limits, a revolutionary strategy, namely metamaterials, is emerging toward engineering structural materials to break the existing fetters. Metamaterials exhibit supernatural physical behaviors, in aspects of mechanical, optical, thermal, acoustic, and electronic properties that are inaccessible in natural materials, such as tunable stiffness or Poisson's ratio, manipulating electromagnetic or elastic waves, and topological and programmable morphability. These salient merits motivate metamaterials as a brand-new research direction and have inspired extensive innovative applications in flexible electronics. Here, such a groundbreaking interdisciplinary field is first coined as “flexible metamaterial electronics,” focusing on enhancing and innovating functionalities of flexible electronics via the design of metamaterials. Herein, the latest progress and trends in this infant field are reviewed while highlighting their potential value. First, a brief overview starts with introducing the combination of metamaterials and flexible electronics. Then, the developed applications are discussed, such as self-adaptive deformability, ultrahigh sensitivity, and multidisciplinary functionality, followed by the discussion of potential prospects. Finally, the challenges and opportunities facing flexible metamaterial electronics to advance this cutting-edge field are summarized.