基于银/高纯铟复合膜的表面等离子体共振折射率传感器

为了解决单一金属膜结构的光纤表面等离子体共振（SPR）盐度传感器结构不稳定且灵敏度较低的问题,设计了一种高灵敏度的锥形三芯光纤结构的SPR盐度传感器。以银膜为激发表面等离子体共振的金属层,在其表面涂覆高纯铟以增强其稳定性。通过Kretschmann四层结构模型对传感器进行理论分析,结果表明,在光纤锥区纤芯模和包层模之间会出现强烈的模式耦合,在覆膜区会激发明显的等离子体共振。对涂覆银膜和高纯铟膜的SPR传感器进行折射率性能测试,在1.4%～3.6%的盐度变化范围内,涂覆银膜和高纯铟膜的SPR传感器灵敏度高达4989.34 nm/RIU,对应的盐度灵敏度为9.1 nm/%,比仅涂覆银膜的SPR传感器灵敏度提高了44%。     

镀银空芯光纤表面等离子体共振传感器的研究

提出了一种新型的基于镀银空芯光纤结构的表面等离子体共振(SPR)传感器。建立了光学模型对传感器内的光传播进行分析,在理论上推导出了传输光谱公式。制作了不同银膜厚度的空芯光纤SPR传感器,搭建了实验系统对内芯充入不同折射率的液体介质的传感器传输光谱进行了测量,获得了相应的SPR光谱。通过理论计算和实验测量对传感器的灵敏度特性和测量准确性进行了分析讨论。结果表明该传感器是一种灵敏度较高的、能实时检测待测高折射率液体介质的SPR传感器,它在一定范围内能够很好地弥补传统光纤表面等离子体共振传感器的不足,并且开拓了空芯光纤的一个新的应用领域。     

利用SPR效应测定可见光波段金膜折射率

利用金膜光纤SPR传感器测定标准试剂折射率,实现了对金膜折射率的测试.给出金膜光纤SPR传感器总反射系数与金膜折射率等参量关系表达式.采用经典金膜折射率计算结果与试验结果相比具有相当差距.为此采用一组标准试剂进行试验,对测试数据进行计算,修正了可见光波段金膜的折射率.     

内置调制层型光纤表面等离子体波共振传感器研究

研究了一种基于内置调制层结构的光纤表面等离子体波共振(SPR)传感器。通过在金膜与纤芯的内侧增覆具有不同厚度和属性的光学透明薄膜作为内调制层,构成了性能独特的光电复合薄膜,起到调节倏逝波矢量和金膜表面等离子体振荡波矢量的双重作用,进而控制共振效应,为调节灵敏度提供依据。采用时域有限差分方法对内置调制层结构光纤SPR共振激励模型属性进行数值仿真。在此基础上,研制了用于液体折射率测量的内置调制层型光纤SPR传感探针。实验结果表明,该传感器在1.335～1.392折射率范围内,随着待测液体折射率的增大,SPR共振光谱向长波方向偏移,且灵敏度达到2263.1nm/RIU,与基于纤芯-金膜-环境介质三层结构的常规光纤SPR传感器相比提高一倍,能够更好地满足环境折射率检测的需求。     

基于全相位滤波技术的光纤表面等离子体共振传感解调算法

基于生物样品检测对折射率传感的迫切需求,构建一种全光纤表面等离子体共振(surface plasmon resonance,SPR)系统,并针对其设计了基于全相位滤波技术的SPR特征波长传感解调算法.基于系统仿真,理论计算了光纤SPR传感器的折射率传感灵敏度.采用全相位滤波技术提取光纤SPR传感器透射光谱的特征波长,理论推导了全相位滤波器的解析表达式.实验结果表明,使用本算法的光纤SPR传感器折射率传感灵敏度为1640.4 nm/RIU,折射率检测的分辨率是7.36×10~(-4)RIU,与传统方法相比,有效提高了系统的检测精度和抗光源扰动性能,降低了实验成本.     

基于表面等离子体共振传感器的金胶体表征

设计了表面等离子体共振(SPR)传感器实验装置,制备了金膜和金纳米胶体溶液,测量了不同厚度金膜和不同浓度金胶体溶液的SPR角谱,得到了不同浓度金胶体溶液的折射率.     

纳米金表面修饰与表面等离子体共振传感器的相互作用研究

为了分析纳米金表面修饰对表面等离子体共振(SPR)的放大作用,以及其对传感器本身的影响,首先,基于色散介质的吸收理论,通过建立波长型SPR生物传感器四层膜结构的数学模型,理论分析了传感器表面所吸附纳米金对传感器的影响:纳米金的表面修饰,改变了表面等离子体传感器中棱镜表面各介质层内电磁场的能量分布,削弱了金属膜在共振吸收中的作用,从而使SPR曲线的半波宽度增加,最小反射系数增大,金膜的最优膜厚度也随之改变.其次,通过不同厚度的金膜外吸附纳米金的对比试验,验证了此理论.金膜厚45nm、表面修饰10nm纳米金颗 关键词： 表面等离子体共振 生物传感器 纳米金 金属膜     

一种用于表面等离子体共振传感器的纳米多孔金膜

为了打破传统的表面等离子体共振(SPR)生物传感器灵敏度不高的限制,近年来纳米材料在SPR生物传感器中的运用得到广泛的研究。但是纳米材料的制备一般都比较困难而且费用高昂,这给研究带来了困难。笔者采用化学腐蚀法制备出一种纳米多孔金膜,利用扫描电子显微镜和光谱仪等测试手段对该金膜的结构和光学性质进行了分析,并将该金膜用于SPR生物传感器实验研究。结果表明,与传统的平面金膜相比,该纳米多孔金膜具有独特的局域表面等离子体共振效应。装配有该金膜的SPR生物传感器在对生物试剂的检测中灵敏度有了一定程度的提高,且该金膜的制备方法简单,成本低廉,完全可以替代传统的平面金膜使用。     

基于表面等离子共振的光纤探针折射率传感器

基于表面等离子体共振效应,设计一种锥形光纤探针折射率传感器。通过锥形结构理论模型与SPR共振模型,利用MATLAB与FDTD Solutions软件进行理论计算与模拟仿真,分析锥形光纤锥度比、传感区长度和银膜厚度对传感器发生共振时的共振深度的影响。通过对比所镀膜层的结构与厚度,从灵敏度与品质因素角度对传感器性能进行优化。结果表明随着锥形光纤锥度比增大,共振深度出现极值;传感区长度越长,共振深度越深;银膜在50 nm处传感器性能较优,银/二氧化钛复合膜结构的传感器灵敏度与品质因素高于单层膜结构传感器。     

基于双峰谐振效应的镀金属长周期光纤光栅液体浓度传感器

利用长周期光纤光栅(LPFG)中的双峰谐振效应,结合表面等离子体共振(SPR)传感器的高灵敏度,提出了一种新型镀金属光纤光栅液体浓度传感器.采用双包层结构模型和耦合模理论,分析r镀金属长周期光纤光栅双峰效应的谐振特性,环境折射率的传感特性以及金属膜厚对双峰LPFG灵敏度的影响.实验上制作了具有双峰效应的镀银膜长周期光纤...     

Surface Plasmon Sensor Based on a Dual Dielectric–Silver Photonic Crystal

We present a new type of biosensor. The principle of operation of the device is similar to conventional surface plasmon sensors, except that the ordinary metallic film in surface plasmon sensors is replaced by a one-dimensional photonic bandgap array. The advantages of using a photonic bandgap structure, instead of a metallic film, include enhanced sensitivity, physical and chemical robustness, and the ability to engineer the optical response of the device. We propose and elaborate a biosensor based on a onedimensional (1D) photonic crystal (PC) with a surface plasmon resonance (SPR). In comparison with standard SPR sensors that use silver (Ag ) or gold (Au) films, PC–Ag–PC–Au structures have narrower resonance widths, lower minimum reflectance, and higher sensitivity, making them a much better choice for biosensing applications. Moreover, the structure is compact (H = 1.139 μm), providing a better option in biosensing in comparison with other PC-SPR and conventional SPR sensors.     

基于表面等离子体共振原理的空芯光纤传感器

设计了一种基于表面等离子体共振原理,使用空芯光纤作为光波导、外表面镀金属膜的光学材料圆柱体作为探头的新型折射率传感器。通过建立光学模型进行分析,在理论上推导出了这种传感器的传输光谱损耗公式,并针对该传感器在不同的光纤长度、探头材料、检测物质折射率等参数设置下的检测性能进行了分析,获得了各种参数对其性能的影响。由于该传感器可针对不同折射率的检测物质灵活地更换合适探头材料,相对于传统的表面等离子体共振光纤传感器,在易用性和性价比等方面具有更好的应用价值。     

Investigation of the performance of an SPR-based optical fiber sensor using finite-difference time domain

Finite-difference time domain (FDTD) method was used to investigate the performance of surface plasmon resonance (SPR)-based optical fiber sensors. The results show that the performance of the fiber sensor can be optimized by choosing a proper combination of metal layer thickness of 40–60 nm and residual cladding thickness of 400–500 nm. Furthermore, the roughness effect of the gold surface layering the fiber sensor is significant in rough surfaces when sigma rms is greater than 5 nm or correlation length is lower than 100 nm.     

Optical cavity coupled surface plasmon resonance sensing for enhanced sensitivity

A surface plasmon resonance (SPR) sensing system based on the optical cavity enhanced detection tech-nique is experimentally demonstrated. A fiber-optic laser cavity is built with a SPR sensor inside. By measuring the laser output power when the cavity is biased near the threshold point, the sensitivity, defined as the dependence of the output optical intensity on the sample variations, can be increased by about one order of magnitude compared to that of the SPR sensor alone under the intensity interrogation scheme. This could facilitate ultra-high sensitivity SPR biosensing applications. Further system miniaturization is possible by using integrated optical components and waveguide SPR sensors.     

表面等离子共振谱半波全宽的算法探讨

根据金属薄膜复介电常量的性质和衬底对表面等离子波波矢的微扰,对在波长调制下的表面等离子共振传感器输出光谱的半波全宽计算方法进行了探讨。建立了输出光谱的半波全宽与传感器各参量之间关系的数学表达式。将理论研究与实验结果进行对比后发现,两者吻合较好。文中的研究结果可为优化传感器的特性提供理论依据。     

Cross-point analysis for a multimode fiber sensor based on surface plasmon resonance

A novel analysis based on surface plasmon resonance (SPR) with a side-polished multimode fiber and a white-light (halogen light) source is presented. The sensing system is a multimode optical fiber in which half of the core has been polished away and a 40 nm gold layer is deposited on to the polished surface by dc sputter. The SPR dip in the optical spectrum is investigated with an optical spectrum analyzer (OSA). In our SPR fiber sensor, the use of liquids with different refractive indices leads to a shift in the spectral dip in the SPR curve. The cross point (CP) of the two SPR spectra obtained from the refractive-index liquid and the deionized water measurements was observed with the OSA. The CP is shifted sensitively in wavelength from 630 to 1300 nm relative to a change in the refractive index of the liquid from 1.34 to 1.46. High sensitivities of 1.9 x 10(-6) refractive-index units (RIUs) in the range of the refractive index of the liquid from 1.40 to 1.44 of 5.7 x 10(-7) RIUs above the value of 1.44 are proposed and demonstrated in our novel SPR analysis.     

Refractive index sensor based on high-order surface plasmon resonance in gold nanofilm coated photonic crystal fiber

We propose a novel kind of wide-range refractive index optical sensor based on photonic crystal fiber(PCF) covered with nano-ring gold film.The refractive index sensing performance of the PCF sensor is analyzed and simulated by the finite element method(FEM).The refractive index liquid is infiltrated into the cladding air hole of the PCF.By comparing the sensing performance of two kinds of photonic crystal fiber structures, a wide range and high sensitivity structure is optimized.The surface plasmon resonance(SPR) excitation material is chose as gold, and large gold nanorings are embedded around the first cladding air hole of the PCF.The higher order surface plasmon modes are generated in this designed optical fiber structure.The resonance coupling between the fundamental mode and the 5 th order surface plasmon polariton(SPP)modes is excited when the phase matching condition is matched.Therefore, the 3 rd loss peaks appear obvious red-shift with the increase of the analyte refractive index, which shows a remarkable polynomial fitting law.The fitnesses of two structures are 0.99 and 0.98, respectively.When the range of refractive indices is from 1.40 to 1.43, the two kinds of sensors have high linear sensitivities of 1604 nm/RIU and 3978 nm/RIU, respectively.     

Numerical simulation of wavelength-modulated surface plasmon resonance-based fiber optic sensor

A systematically theoretical analysis of a surface plasmon resonance (SPR)-based optical fiber sensor is carried out. A three-layer mode (fiber core/gold/sample) is used to simulate the SPR-based optical fiber sensor. Several parameters including the thickness of gold layer, numerical aperture (NA) of fiber, sensing region length and fiber core diameter have been investigated to evaluate the sensitivity and measurement accuracy of sensor. A detailed explanation for the effect of these parameters on the sensor is presented to give a guideline to optimally design the SPR-based optical fiber sensor.     

侧边抛磨的U型金溅射塑料光纤等离子体共振传感器

为了测量溶液折射率变化，对塑料光纤纤芯表面的纤芯-金层-液体的3层膜结构进行研究，制作了一种使用U型结构并结合侧边抛磨方法的表面等离子体共振传感器。将截取的一段塑料光纤弯曲成为U型，并在烘箱中通过较高温度使这段光纤的曲率固定，对弯曲部分的外表面进行抛光，暴露该位置塑料光纤芯层并在其上溅射金纳米薄膜层，将制备好的传感器浸入不同折射率的液体中，使用光谱分析仪观察光谱的移动。实验结果表明:当塑料光纤SPR传感器测量折射率变化范围在1.333~1.406的液体时，可以通过光谱观察到随着液体折射率的增大，等离子体共振吸收峰位置也不断地向波长增大的方向移动，并且二者之间存在线性关系，其灵敏度为7.5×10-4 RIU/nm。该传感器探头具有灵敏度高、小型化、易制备、低成本的特点。