基于光学塔姆等离子体激元的新型传感概念。
Novel sensing concept based on optical Tamm plasmon.
作者信息
Zhang Wei Li, Wang Fen, Rao Yun Jiang, Jiang Yao
出版信息
Opt Express. 2014 Jun 16;22(12):14524-9. doi: 10.1364/OE.22.014524.
PMID:24977548
Abstract
This paper proposes a novel concept of refractive index sensing taking advantage of a high-refractive-index-contrast optical Tamm plasmon (OTP) structure, i.e., an air/dielectric alternate-layered distributed Bragg reflector (DBR) coated with metal. In the reflection spectrum of the structure, a dip related to the formation of OTP appears. The wavelength and reflectivity of this dip are sensitive to variation of ambient refractive index, which provides a potential way to realize refractive index sensing with a large measuring range and high sensitivity.
摘要
本文提出了一种利用高折射率对比度光学塔姆等离子体(OTP)结构进行折射率传感的新概念,即一种涂覆有金属的空气/电介质交替层分布式布拉格反射器(DBR)。在该结构的反射光谱中,出现了一个与OTP形成相关的凹陷。该凹陷的波长和反射率对环境折射率的变化敏感,这为实现大测量范围和高灵敏度的折射率传感提供了一种潜在方法。
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