预聚集法制备单层银纳米粒子膜及其SERS活性研究

提出一种预聚集方法来制备单层银纳米粒子膜, 获得了高活性的表面增强拉曼散射基底. 利用紫外-可见吸收光谱、TEM, SEM等表征手段分析了预聚集程度对银纳米单层膜基底SERS活性的影响. 实验发现该方法制备的银纳米粒子膜的SERS活性与预聚集程度直接相关, 在最优参数下制备的SERS基底具有银颗粒分布均匀、SERS活性均一、增强效果好等优点. 实验分别以罗丹明6G (R6G)、3-巯基丙酸(3MPA)和9-氨基吖啶盐酸盐(9AA)为探针对所制备基底的SERS活性进行了测试, 结果均获得了高信噪比的SERS信号.     

银纳米粒子簇的设计、 制备和表面增强拉曼光谱

通过匹配激光光斑直径与胶体微球的尺寸, 设计制备了银纳米粒子的表面增强拉曼散射(SERS)基底, 并将其用于研究单个银纳米粒子簇的表面增强拉曼光谱. 在制备纳米粒子的过程中, 考察了等离子体刻蚀时间与银沉积厚度对“单”银纳米粒子结构与形貌的影响. 将吡啶、 巯基苯和罗丹明R6G作为SERS探针分子, 研究了其SERS效应, 通过荧光共振能量转移(FRET)机理, 实现了染料分子在单银纳米粒子簇上的SERS效应. SERS光谱测试与相关计算结果表明, 单个银纳米粒子簇的拉曼增强因子能够达到约10⁶.     

一种新型表面增强拉曼活性基底的制备方法

表面增强拉曼光谱技术 (SERS)具有极高的灵敏度 ,对某些分子其灵敏度比常规拉曼光谱高一百万倍 ,能检测吸附在金属表面的单分子层和亚单分子层的分子 ,并提供丰富的分子结构信息 [1～ 5] .活性基底的制备是获得 SERS信号的前提 ,电化学粗糙化的电极、贵金属溶胶及真空蒸镀的金属岛膜是SERS分析中最常用的 3种活性基底 ,在实际应用中各有利弊 .本文报道一种新的制备银纳米粒子基底的方法 ,可使银纳米粒子生长到合适的尺寸 ,以达到最佳SERS增强效果 .利用紫外 -可见光谱和 AFM研究该 SERS基底纳米粒子的尺寸分布和形貌 ,以 1 ,4-(双…     

用3A分子筛作模板构建灵敏的表面增强拉曼光谱银基底

成功地制备了一种灵敏的表面增强拉曼散射(SERS)银基底。即以3A分子筛为模板,以葡萄糖为还原剂,通过改善的银镜反应在分子筛上建构银壳,再用稀氢氟酸去掉分子筛核制备由带有平的内表面的平板堆砌而成的聚集体。通过扫描电子显微镜观测了其大小和形貌,通过X-射线粉末衍射仪研究了其结构。以4-羟基苯硫酚(4-MPH)为探针分子,考察了其SERS活性,与在玻璃基底上构建的银纳米粒子和商品微米银粉末相比,吸附在该平板银聚集体上的4-MPH在~1078 cm-1处谱带的SERS峰强度是吸附在以玻璃为基底的银纳米粒子的40倍左右,是吸附在商品微米银粉末的13倍左右。通过计算,该SERS活性基底的增强因子约为2.8×105。这种灵敏的SERS基底容易制备,成本合适,在设计、开发SERS光谱探针装置等方面有很好的应用前景。     

复合SERS基底的构建及性质

通过自组装方法以对巯基苯胺(PATP)为偶联分子, 在石英基片上构筑了多种形貌的银钠米粒子单层结构和三明治结构. 研究了组装膜在不同激发线下表面增强拉曼散射(SERS)的增强差异. 研究结果表明, 单层基底和三明治基底中偶联分子的SERS信号因银纳米粒子间的电磁场耦合而显著增强, 且在三明治结构中增强更加明显. 对复合SERS基底增强因子进行计算可知, 复合SERS基底的表面等离子体共振(SPR)峰与激发线的匹配程度越好, 其增强因子越大. 在三明治结构中更易发生PATP分子转变为对巯基偶氮苯(DMAB)分子的激光诱导催化偶联反应. 另外, 该激光诱导催化偶联反应与激发波长密切相关.     

基于自组装纳米金单层膜的全内反射SERS研究

采用静电自组装技术分别在玻璃基片和30 nm厚的金膜表面固定一层金纳米粒子（GNP）制得两种表面增强拉曼散射（SERS）基底,然后通过棱镜全内反射（TIR）激励和背向收集模式分别测试了两种基底上吸附的染料单分子层SERS光谱. 实验结果表明两种SERS基底的拉曼增强效果均高度依赖于入射激光的偏振状态,对于玻璃/纳米金SERS基底,s 光全内反射导致的拉曼增强因子是线偏振光（p）光的2-5 倍,说明该基底上的“热点”位于纳米金单层膜内相邻粒子之间;对于玻璃/金膜/纳米金SERS基底,只有采用p光在特定的全内反射角下才能激发SERS信号,而且测得的SERS信号比玻璃/纳米金基底增强了近30 倍. 究其原因是p 光在金膜表面共振激发的传播表面等离子体与纳米金局域表面等离子体耦合,进而导致显著场增强. 实验结果指出在背向收集模式下,由p 光激发的SERS信号是非偏振光,包含强度几乎相等的s 和p 成分. 利用玻璃/金膜/纳米金基底还实现了拉曼光定向发射和收集,测得的SERS信号是p光.     

基于自组装纳米金单层膜的全内反射SERS研究

采用静电自组装技术分别在玻璃基片和30 nm厚的金膜表面固定一层金纳米粒子(GNP)制得两种表面增强拉曼散射(SERS)基底,然后通过棱镜全内反射(TIR)激励和背向收集模式分别测试了两种基底上吸附的染料单分子层SERS光谱.实验结果表明两种SERS基底的拉曼增强效果均高度依赖于入射激光的偏振状态,对于玻璃/纳米金SERS基底,s光全内反射导致的拉曼增强因子是线偏振光(p)光的2-5倍,说明该基底上的"热点"位于纳米金单层膜内相邻粒子之间;对于玻璃/金膜/纳米金SERS基底,只有采用p光在特定的全内反射角下才能激发SERS信号,而且测得的SERS信号比玻璃/纳米金基底增强了近30倍.究其原因是p光在金膜表面共振激发的传播表面等离子体与纳米金局域表面等离子体耦合,进而导致显著场增强.实验结果指出在背向收集模式下,由p光激发的SERS信号是非偏振光,包含强度几乎相等的s和p成分.利用玻璃/金膜/纳米金基底还实现了拉曼光定向发射和收集,测得的SERS信号是p光.     

在铜箔上电辅助制备纳米银及其SERS应用研究

在电化学工作站上以铜箔为工作电极,以硝酸银和PVP混合液作为前驱溶液,利用循环伏安法电辅助制备了纳米银,得到在铜箔上紧密均匀分布的纳米银颗粒聚集体作为SERS基底。通过X射线粉末衍射、X射线光电子能谱、扫描电子显微镜等表征手段,对铜箔上负载的银纳米颗粒进行了形貌和成分的表征,探讨了PVP及电辅助方法对纳米银形貌及基底SERS活性的影响。以4-巯基吡啶和罗丹明6G为探针溶液研究了制备基底的SERS活性,同时还对基底的均匀性进行了研究,结果表明所制备的SERS基底具有良好的性能。     

银包覆金纳米粒子膜的制备、表征及其SERS效应

本文研究了通过液相微波高压技术和自组装方法相结合制备的复合纳米粒子膜。首先, 将利用微波加热制备的金纳米粒子组装到石英片上,然后,再通过微波加热方法在石英片上的金颗粒表面沉积生长银包裹层, 用UV-Vis吸收光谱和原子力显微镜对该结构的复合纳米粒子膜进行表征。研究表明：通过在微波高压反应中调节银的沉积量可以有效控制包覆层的厚度和复合粒子的尺度。相对金纳米粒子膜,制备的复合粒子膜能显著的提高SERS能力,而较大的复合粒子的银壳层和粒子之间的耦合作用对复合粒子膜的SERS活性的显著增强起主要作用。     

结合化学组装和电沉积的SERS基底的制备方法

采用一种结合化学组装和电化学沉积制备均匀而且具有强SERS基底的方法, 研究了沉积电位对组装在ITO表面的金纳米粒子形貌的影响, 发现在-0.04 V下沉积5 min可以得到形貌均匀的纳米粒子. 利用现场电化学紫外-可见吸收光谱来监控电化学沉积过程, 发现沉积一定时间后, 紫外-可见吸收谱在600~700 nm区间出现新峰, 表明粒子间发生了有效的电磁场耦合. 对制备的基底进行拉曼成像, 结果表明, 基底的均匀性很好, 最强点与最弱点的d信号差小于20%, 符合商品化基底的要求.     

Preparation of Surface-enhanced Raman Scattering(SERS)-active Optical Fiber Sensor by Laser-induced Ag Deposition and Its Application in Bioidentification of Biotin/Avidin

A surface-enhanced Raman scattering(SERS) optical fiber sensor was prepared by the laser-induced deposition of Ag nanoparticle membrane on a silica optical fiber tip, which was applied to the real time SERS spectral monitoring on the biorecognition of biotin/avidin. The bioidentification of biotin/avidin was carried out through a indirect method, in which the bioidentification is based on the SERS response signal of a labeled dye(Atto610) after its fluorescence has been quenched totally by the deposited Ag nanoparticle membrane. By SERS monitoring the bioidentification process of biotin/avidin, it has been found that this recognition process is finished in 40 min. The lowest detection concentration of biotin is 1.0×10^-7 mg/mL. This research is promising in the application of immunoassays on line and in vivo.     

Ag纳米粒子修饰光纤探针在等离激元催化反应中的应用

本文发展了一种基于Ag纳米粒子(AgNPs)修饰的局域表面等离激元共振(LSPR)光纤探针,作为等离激元催化反应基底同时原位检测表面增强拉曼光谱(SERS)信号,实现反应与检测一体化。本文使用(3-氨基丙基)三甲氧基硅烷(APTMS)分子将AgNPs组装到光纤探针表面。通过调控自组装时间,可形成AgNPs均匀分布的探针。以对巯基苯胺(PATP)作为反应的模型分子,获得了较好的等离激元催化及信号检测效果。在相同光源条件下,从光纤内部激发收集所得产物的SERS信号强度为外部激发收集的12.8倍,表明内激发收集方式在反应及信号检测方面具有优势;在一定浓度范围(10~(-4)–10~(-8)mol·L~(-1))内可用该光纤探针对PATP溶液进行定量分析;运用该光纤探针开展了等离激元催化PATP分子偶联反应的原位动力学研究。该LSPR光纤探针具有较高灵敏度,对样品损伤小,可在多场合下实现原位检测,且制备简便、成本较低。还有望结合近场扫描光学显微技术进一步对样品表面进行微区等离激元催化反应及检测并得到反应的二维分布图。     

SERS活性光纤光谱微探针研究

用真空蒸镀银岛膜和银溶胶自组装膜两种方法对光纤探针进行表面增强拉曼(SERS)活性修饰,构造了圆锥型SERS活性光纤光谱微探针.选取几个有代表性的分子作为检测样品,得到了低浓度样品的SERS光谱,对样品BVPP的检测下限达到10^-9mol/L.比较两种修饰光纤探针的检测结果可知,银溶胶自组装膜修饰更有优势.     

覆银聚酰亚胺纳米棒阵列的制备及其SERS特性

通过在聚酰亚胺(PI)膜表面进行氧等离子体刻蚀得到纳米棒阵列,并溅射Ag膜形成了覆银聚酰亚胺纳米棒阵列。利用该方法能够简单快捷地制备出具有较强活性且结构可调的表面增强拉曼散射(SERS)衬底。通过改变氧等离子体刻蚀时间和溅射Ag膜厚度可以调节覆银PI纳米棒的间隙、密度和直径。通过对探针分子尼罗兰(NB)测试表征了覆银PI纳米棒衬底的SERS增强能力。通过改变氧等离子体刻蚀时间和Ag膜溅射厚度实现了衬底SERS增强能力的调节。在氧等离子体刻蚀时间为30 s和溅射Ag膜厚度为70 nm时,衬底的SERS增强能力达到最强,并且其拉曼信号展现出较好的一致性。     

Photochemical modification of an optical fiber tip with a silver nanoparticle film: a SERS chemical sensor

We present a method of photochemical modification of an optical fiber tip with a silver nanoparticle film. The deposited silver nanoparticle film displays alternating light and dark circles, which are similar to a radial diffraction pattern. The modified optical fiber is examined as a chemical sensor for in situ detection. The modified fibers show excellent SERS activity, a low limit of detection (LOD), and good reproducibility. The maximum SERS activity of the sensor was achieved within 5.0 min of deposition. Thus, the method is also quite rapid.     

Thin films of Ag nanoparticles prepared from the reduction of AgI nanoparticles in self-assembled films

A novel method for the preparation of thin films of Ag nanoparticles is reported. Using mercaptoacetic acid as the stabilizing agent, AgI nanoparticles were prepared in aqueous solution. And based on electrostatic interactions, the thiol-passivated AgI nanoparticles were assembled in a self-assembled film by alternative deposition with a cationic polyelectrolyte. Then the AgI nanoparticles in the composite film were reduced by NaBH(4), which resulted in the formation of a thin film of Ag nanoparticles. UV-visible spectra and X-ray photoelectron spectroscopy data confirmed the transformation from AgI to Ag. Atomic force microscopy (AFM) showed that the formed Ag nanoparticles distributed on the film homogeneously. Surface-enhanced Raman spectroscopy (SERS) measurement indicated that the prepared thin films could be used as effective SERS substrates. The reduction process was also carried out by UV light at selective surface regions, which resulted in the formation of patterned nanoparticle arrays.     

Easy deposition of Ag onto polystyrene beads for developing surface-enhanced-Raman-scattering-based molecular sensors

We describe a very simple electroless plating method that can be used to prepare Ag-coated polystyrene beads. Robust Ag nanostructures are reproducibly fabricated by soaking polystyrene beads in ethanolic solutions of AgNO(3) and butylamine. When the molar ratio of butylamine to AgNO(3) is far below 1.0, distinct nanosized Ag particles are formed on the polystyrene beads, but by increasing the amount of butylamine, network-like Ag nanostructures are formed that possess very broad UV/vis absorption characteristics extending from the near-UV to near-infrared regions. In conformity with the UV/vis absorption characteristics, the Ag-deposited polystyrene beads were highly efficient surface-enhanced Raman scattering (SERS) substrates, with an enhancement factor estimated using 4-aminobenzenethiol (4-ABT) as a model adsorbate to be larger than 1.1x10(6). On the basis of the nature of the SERS peaks of 4-ABT, those Ag-deposited polystyrene beads were confirmed, after attaching biotin groups over 4-ABT, to selectively recognize streptavidin molecules down to concentrations of 10(-11) g mL(-1) (i.e., approximately 0.2 pM). Since a number of different molecules can be used as SERS-marker molecules (such as 4-ABT), multiple bioassays are readily accomplished via SERS after attaching appropriate host or guest molecules onto them.     

Surface-enhanced Raman scattering characteristics of 4-nitrobenzenethiol adsorbed on palladium and silver thin films

Palladium is an important catalytic metal, and it is desirable to develop a surface-enhanced Raman scattering (SERS) technique to investigate the reagent and product species adsorbed on its surface. Unfortunately, Pt-group metals, e.g., Pt and Pd, have been commonly considered as non- or weak-SERS-active substrates. In this work, Ag and Pd thin films were deposited very efficiently and evenly onto the surface of glass substrates by using only corresponding metal nitrate salts (AgNO₃ and Pd(NO₃)₂) with butylamine in ethanolic solutions. In this process, pure ethanol was used for Ag deposition, while an ethanol–water (8:2) mixture was used for Pd deposition. The as-prepared Ag and Pd films exhibited SERS activity over a large area. The surface-induced photoconversion capabilities of these Ag and Pd films were then tested on 4-nitrobenzenethiol by means of SERS. It was found that at least under visible laser irradiation, the surface-catalyzed photoreaction occurs more readily on a Ag film than on a Pd film for the conversion of 4-nitrobenzenethiol to 4-aminobenzenethiol, even though Pd is known to be an important transition metal with high catalytic activity.     

Surface-enhanced Raman spectroscopy: substrate-related issues

After over 30 years of development, surface-enhanced Raman spectroscopy (SERS) is now facing a very important stage in its history. The explosive development of nanoscience and nanotechnology has assisted the rapid development of SERS, especially during the last 5 years. Further development of surface-enhanced Raman spectroscopy is mainly limited by the reproducible preparation of clean and highly surface enhanced Raman scattering (SERS) active substrates. This review deals with some substrate-related issues. Various methods will be introduced for preparing SERS substrates of Ag and Au for analytical purposes, from SERS substrates prepared by electrochemical or vacuum methods, to well-dispersed Au or Ag nanoparticle sols, to nanoparticle thin film substrates, and finally to ordered nanostructured substrates. Emphasis is placed on the analysis of the advantages and weaknesses of different methods in preparing SERS substrates. Closely related to the application of SERS in the analysis of trace sample and unknown systems, the existing cleaning methods for SERS substrates are analyzed and a combined chemical adsorption and electrochemical oxidation method is proposed to eliminate the interference of contaminants. A defocusing method is proposed to deal with the laser-induced sample decomposition problem frequently met in SERS measurement to obtain strong signals. The existing methods to estimate the surface enhancement factor, a criterion to characterize the SERS activity of a substrate, are analyzed and some guidelines are proposed to obtain the correct enhancement factor.     

Porous GaN as a template to produce surface-enhanced Raman scattering-active surfaces

Surface-enhanced Raman spectroscopy (SERS) substrates have been prepared by depositing Au or Ag on porous GaN (PGaN). The PGaN used as the template for the metal deposition in these studies was generated by a Pt-assisted electroless etching technique. PGaN was chosen as a potential SERS template due to its nanostructured surface and high surface area, two characteristics that are important for SERS substrates. Metal films were deposited either by solution-based electroless deposition or by thermal vacuum evaporation. SERS spectra were recorded at lambda = 752.5 nm for Au films and at lambda = 514.5 nm for Ag films deposited on PGaN. The SERS signal strength across the metal coated PGaN substrates was uniform and was not plagued by "hot" or "cold" spots on the surface, a common problem with other SERS surfaces. The Ag film deposited by electroless deposition had the highest overall SERS response, with an enhancement factor (EF) relative to normal Raman spectroscopy of 10(8). A portion of the increase in EF relative to typical SERS-active substrates can be assigned to the large surface area characteristic of the PGaN-Ag structures, but some of the enhancement is intrinsic and is likely related to the specific morphology of the metal-nanopore composite structure.