超材料
掩蔽
太赫兹辐射
薄膜
材料科学
光电子学
谐振器
微测辐射热计
等离子体子
分裂环谐振器
光学
折射率
消光比
共振(粒子物理)
电介质
波长
负折射
相变
凝聚态物理
纳米技术
物理
探测器
原子物理学
热辐射计
作者
Minah Seo,Jisoo Kyoung,Hyeong‐Ryeol Park,Sukmo Koo,Hyun-sun Kim,Hannes Bernien,Bong Jun Kim,Jong Ho Choe,Y. H. Ahn,Hyun-Tak Kim,Namkyoo Park,Q‐Han Park,Kwangjun Ahn,Dai‐Sik Kim
出处
期刊:Nano Letters
[American Chemical Society]
日期:2010-05-14
卷期号:10 (6): 2064-2068
被引量:362
摘要
Unusual performances of metamaterials such as negative index of refraction, memory effect, and cloaking originate from the resonance features of the metallic composite atom(1-6). Indeed, control of metamaterial properties by changing dielectric environments of thin films below the metallic resonators has been demonstrated(7-11). However, the dynamic control ranges are still limited to less than a factor of 10,(7-11) with the applicable bandwidth defined by the sharp resonance features. Here, we present ultra-broad-band metamaterial thin film with colossal dynamic control range, fulfilling present day research demands. Hybridized with thin VO(2) (vanadium dioxide) (12-18) films, nanoresonator supercell arrays designed for one decade of spectral width in terahertz frequency region show an unprecedented extinction ratio of over 10000 when the underlying thin film experiences a phase transition. Our nanoresonator approach realizes the full potential of the thin film technology for long wavelength applications.
科研通智能强力驱动
Strongly Powered by AbleSci AI