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多元等离子体共振纳米结构的飞秒激光加工与拉曼检测应用
引用本文:冯艳硕,梁密生,卞晓蒙,任光辉,边洪录,祝连庆. 多元等离子体共振纳米结构的飞秒激光加工与拉曼检测应用[J]. 红外与激光工程, 2023, 52(4): 20220522-1-20220522-9. DOI: 10.3788/IRLA20220522
作者姓名:冯艳硕  梁密生  卞晓蒙  任光辉  边洪录  祝连庆
作者单位:1.北京信息科技大学 光电信息与仪器北京市工程研究中心,北京 100016
基金项目:国家重点研发计划(2021YFB3201303);北京市科技新星计划(Z211100002121075);北京市教育委员会科学研究计划项目资助(KM202211232016)
摘    要:以多元金属纳米薄膜(金、银)为基底,利用飞秒激光加工技术制备得到多元等离子体纳米结构,并研究了其局域表面等离子体共振效应(Local Surface Plasmon Resonance,LSPR)和表面增强拉曼散射(Surface Enhanced Raman Scattering,SERS)性能。利用时域有限差分(Finite Difference Time Domain,FDTD)软件模拟了不同情况下(单层金膜、金银双层金属薄膜的平面以及阵列结构)的电场分布情况。根据仿真结果,相较于平面金属膜来说,飞秒激光制备的微纳结构阵列附近区域产生电磁场增强,集中在结构边缘处,且其强度变化与预期结果基本保持一致。此外,使用浓度为10-4 M和10-6 M的罗丹明(R6G)溶液进行SERS性能测试。测试的结果表明,单层平面金膜基本没有SERS峰值信号出现,而单层金膜上制备的等离子体纳米结构附近出现峰值信号,双层金属薄膜上制备的等离子体纳米结构展现出更高的SERS峰值信号。多元金属等离子体纳米结构展示出更强的局域表面等离子体共振效应,从而在表面增强拉曼散射、光催化、生物传感等领域具有广泛的应用。

关 键 词:飞秒激光加工  多元等离子体纳米结构  局域表面等离子体共振  表面增强拉曼散射
收稿时间:2022-07-27

Femtosecond laser processing and Raman detection applications of multi-plasmon resonance nanostructures
Affiliation:1.Beijing Engineering Research Center of Optoelectronic Information and Instrument, Beijing Information Science & Technology University, Beijing 100016, China2.School of Instrumentation Science and Optoelectronic Engineering, Beijing Information Science & Technology University, Beijing 100192, China3.Beijing Spacecrafts, China Academy of Space Technology, Beijing 100094, China
Abstract:  Objective   Plasma nanostructures composed of multiple metals have been widely applied in various fields such as photocatalysis, medical imaging, solar cells, surface-enhanced Raman scattering (SERS), biosensors, and information technology, due to their localized optical near-field properties and surface plasmon resonance effects. Compared with single-metal nanostructures, multi-metal plasma nanostructures exhibit significant enhanced resonance effects in the UV-VIS wavelength range. At present, there are few studies on multi-metal plasmonic nanostructures, and the fabrication methods are complicated, such as tedious processing, poor controllability, and long preparation period. Therefore, in this study, a scheme based on multi-metal thin film plasma nanostructures was designed, and simulation methods were used to demonstrate that the designed multi-metal plasma nanostructures have the characteristic of enhanced electric field. Furthermore, multi-metal plasma nanostructures were fabricated and evaluated using Rhodamine 6G (R6G) with a femtosecond laser direct writing system, demonstrating the enhanced SERS signal of the structure.  Methods   This article describes the construction of a femtosecond laser direct writing system. A titanium-sapphire oscillator laser (with an output power of 3.5 W, a central wavelength of 800 nm, and a repetition frequency of 85 MHz) is used as the femtosecond laser source (Fig.1). Magnetron sputtering technology was used to deposit a dual-layered gold-silver metal film on a silicon dioxide substrate. Rhodamine (R6G) solution was used as the test molecule for evaluating the SERS performance of multi-metal plasmonic nanocavity structures. Confocal Raman spectroscopy imaging was used to analyze the SERS performance of the multi-metal plasmonic nanocavity structures.  Results and Discussions   A multi-metal plasmonic nano-cavity structure was fabricated using a femtosecond laser direct writing system. Different sizes of nanoparticles were produced by adjusting the laser power and pulse irradiation time. The three-dimensional morphology of the experimental results was characterized using AFM and SEM, verifying the size variation law of multi-metal plasmonic nanostructures fabricated by femtosecond laser processing (Tab.1, Tab.2). The FDTD simulation software was used to simulate and analyze the changes in the electric field intensity. The electric field distribution of the planar metal was clearly reorganized, mainly concentrated at the edge of the metal plasmonic nanostructure, and the electric field intensity of the multi-metal plasmonic nanostructure was significantly enhanced compared to that of the single metal, usually manifested as an increase in the localized surface plasmon resonance effect (Fig.2, Fig.3). Evaluation using Rhodamine (R6G) solution showed that the gold-silver bilayer metal plasmonic nanostructure exhibited a stronger Raman signal, while the single-layer planar metal film still did not show any peak (Fig.5, Fig.6).  Conclusions   Based on the high-precision, high-flexibility, simple and convenient femtosecond laser processing technology, the metal plasmonic nanostructures were directly fabricated on the surface of metal thin films in this study. Through continuous optimization of processing parameters, uniform and regular nanostructures were obtained, and the structure was characterized to demonstrate the significant enhancement of localized surface plasmon resonance in multi-metal plasmonic nanostructures. Surface-enhanced Raman scattering (SERS) signal enhancement was verified using Rhodamine (R6G). The Raman test results showed that the structure had excellent SERS signal enhancement performance. Experimental simulations were performed using FDTD software, and the results showed that the electric field intensity between multi-metal plasmonic nanostructures was significantly enhanced. Femtosecond lasers can be used to process any material, such as semiconductors, polymers, alloys, and others, with various processing methods. In the future, spatiotemporally shaped femtosecond laser direct writing technology will be used to expand the size processing range of femtosecond lasers and control more material properties.
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