项目名称: 基于非对称金属包覆介质波导结构的亚波长光栅刻写及其SERS应用
项目编号: No.61505074
项目类型: 青年科学基金项目
立项/批准年度: 2016
项目学科: 无线电电子学、电信技术
项目作者: 王向贤
作者单位: 兰州理工大学
项目金额: 20万元
中文摘要: 亚波长光栅是光子学中至关重要的一种基本元件,其制备和应用均是当前微纳光子学领域的研究重点。本项目中,申请人拟基于非对称金属包覆介质波导结构,实现周期可调的大面积亚波长光栅刻写并将其应用于SERS研究。理论上,通过数值模拟和理论分析手段,研究波导结构中存在的导波模式、表面等离子体模式及其刻写的亚波长光栅的周期与光刻胶薄膜厚度之间的关系。实验上,用442nm、325nm激光激发波导结构中的导模、表面等离子体干涉场,刻写制备各种周期的金属薄膜/亚波长介质光栅结构。在此基础上,将金属薄膜/亚波长介质光栅与金属纳米颗粒的耦合结构作SERS基底。通过理论分析与数值模拟,研究该耦合结构中表面等离子体、局域表面等离子体的激发及其强共振耦合条件和诱导的电场增强,揭示耦合结构提高SERS信号强度的物理机理,进而发展成本低廉、操作简单的高灵敏度SERS检测技术。
中文关键词: 表面等离激元;亚波长光栅;导模;光刻;表面增强拉曼散射
英文摘要: Sub-wavelength gratings is a critical element in photonics. So its fabrication and application has attracted a great deal of research attention. In this proposal, we plan to realize an adjustable period and large area sub-wavelength gratings inscribing based on asymmetric metal-cladding dielectric waveguiding structure and to apply the gratings in SERS research. Numerical simulation and theoretical analysis will be used to investigate the dependency of the waveguide modes, the surface plasmons modes existing in the waveguiding structure and the period of the sub-wavelength gratings inscribed to the thickness of the resist in detail. The 442nm and 325nm laser will be used to excite interference field of the waveguide modes or surface plasmons in the waveguiding structure, which will be used to fabricate the metal film/sub-wavelength dielectric gratings structure with various period. On this basis,the coupling structure of the metal film/sub-wavelength dielectric grating and metal nanoparticles will be used as SERS substrates. Theoretical analysis and numerical simulation will be used to investigate the excitation of surface plasmons and localized surface plasmons, the condition of high resonant coupling and its field enhancement, which may reveal the physical mechanism of high SERS signal enhancement within the coupling structure. Further more, the SERS detecting techniques with low cost, simple operation and high sensitive will be developed.
英文关键词: surface plasmons;sub-wavelength gratings;waveguide modes;lithography;surface-enhanced Raman scattering