甲基橙在银镜上的表面增强拉曼光谱研究

利用表面增强拉曼光谱(SERS)技术研究了甲基橙的(MO)的SERS谱,对拉曼峰进行了指认,并给出了甲基橙在银镜上的吸附状态。     

酸性金黄偶氮染料在银镜上的表面增强拉曼光谱研究

以银氨溶液和葡萄糖制备的银镜为吸附基底,获得了酸性金黄G偶氮染料在银镜上的表面增强拉曼光谱,并对其拉曼峰的归属及吸附机理进行了探讨。酸性金黄G靠静电引力和范德华力以带孤对电子的N原子垂直吸附在银镜表面,SERS强度随染料浓度的降低而降低,检出限为10-10mol/L。     

胞嘧啶吸附在粗糙银和金电极上的表面增强拉曼光谱

利用电化学伏安方法和表面增强拉曼光谱(SERS)技术研究了在-1.0V~0V的电位区间内胞嘧啶在粗糙银电极和金电极表面上的吸附行为。结果表明,在所研究的电位区间,胞嘧啶通过N3位垂直吸附在粗糙银和金电极表面,且当电位负移时吸附作用减弱。     

钴钯铂的表面增强喇曼散射效应研究

利用天线共振子模型对钴钯铂的表面增强喇曼散射特性进行了计算和分析, 计算结果表明钴钯铂的增强分别为1、≤4、2～4, 实验测量的最大增强分别为≤5、105和140, 在考虑化学增强的情况下, 理论同实验是一致的; 在经氧化还原过程处理的钴钯铂片上做了核酸碱基胞嘧啶的SERS谱, 结果反映三种衬底上的SERS谱强弱不同, 以铂最大, 钴最小, 而且, 三种衬底对于胞嘧啶各振动模式的增强基本一致.     

银分子中电荷转移效应及其对喇曼信号的增强研究

本文从观察光的吸收谱变化觉察到分子吸附在银胶、银镜上所出现的电荷转移跃迁;同时测量了电荷转移对吸附分子喇曼信号的增强.并且对其机理进行了初步分析.     

药用乳酸钙的SERS研究

利用银镜作为衬底,本文对乳酸钙的表面增强喇曼散射效应进行了研究.分析表明,乳酸钙分子在银镜上的吸附因缺少活位而不能产生明显的增强效应.Cl^-的加入使得银镜表面活位得以稳定和增加,从而使乳酸钙在银镜衬底上显示出较强的增强效果.通过对混合溶液进行研究,发现乳酸钙和吡啶在银镜上的吸附相互独立,互不影响.     

胞嘧啶在沉积激光烧蚀Ag纳米颗粒电极上的SERS分析

用Nd:YAG激光器在二次去离子水中烧蚀银片,制备出了尺度分布均匀、并且具有很好的稳定性的"化学纯净"的Ag胶体系,并在电化学体系中将这种银胶沉积在粗糙的银电极表面,研究了胞嘧啶分子吸附在沉积Ag纳米颗粒电极表面随电极电位改变的表面增强拉曼光谱(SERS)。分析表明:(1)沉积银纳米颗粒的电极将金属电极与金属溶胶体系各自的优势很好的结合起来,形成了一种高效的SERS活性基底。(2)胞嘧啶在沉积银颗粒的电极表面以N3位竖直吸附,并且随着电位的负移,大多数SERS峰的位置发生了红移,表明胞嘧啶在电极表面吸附作用减弱。     

表面增强拉曼光谱研究胞嘧啶在银胶上的吸附行为

为探讨胞嘧啶(Cytosine,Cy)在基底银表面的吸附特性和规律,采用表面增强拉曼散射(SERS)光谱对其吸附行为进行分析,并结合量子化学密度泛函理论(DFT)/B3LYP计算方法对Cy分子的常规拉曼光谱(NRS)及Cy与Ag团簇吸附的SERS光谱进行计算,与测定结果进行比对且对其拉曼峰进行系统指认及归属,理论计算结合实测值探讨了Cy在基底Ag上的增强效应和吸附行为。考察了Cy分子在Ag纳米粒子上的不同吸附时间、浓度、pH等条件对SERS光谱的影响及优化,发现pH影响最大,在中性和强碱性条件下的增强效应明显优于酸性。Cy分子存在2种不同的异构体和3种不同的存在形态,并随酸度变化相互转化而达动态平衡。基于Cy在不同pH时的形态分布和相应的SERS变化规律,结合DFT算得的Cy分子中的电荷分布及在银基底表面的吸附机制,详细探讨了酸碱对Cy分子的SRES光谱影响的内因和吸附机理,指出在中性和弱碱性时,是Cy中的N3和O与Ag形成配位吸附;在pH大于11时,N与Ag形成配位吸附,而O与Ag形成共价吸附。     

DNA碱基在银镜上的表面增强拉曼散射

首次采用表面增强拉曼散射(SERS)研究不同组分相互作用的动态变化过程,指出了脱氧核糖核酸(DNA)互补碱基对(胞嘧啶和鸟嘌呤:腺嘌呤和胸腺嘧啶)之间的氢键缔合作用为二级反应动力学过程,提出了DNA碱基在银镜表面的增强机制的[Ag—Cl—(氢键)—碱基]的氢键模式。     

利用SERS效应研究表面吸附动力学过程

本文提出了利用表面增强喇曼散射(SERS)效应研究表面吸附动力学过程的设想.基于此设想,我们对固-液界面吸附动力学进行了理论探讨,讨论了SERS信号强度随时间的依赖性,从而得到有关表面吸附动力学参量,并利用银胶体系对对氨基苯甲酸的吸附动态过程进行初步实验研究.结果表明,利用SERS效应对表面吸附动力学、尤其是微量吸附动力学的研究是非常有效的. 关键词：     

巯基苯并咪唑在银电极表面的自组装吸附特性及表面增强拉曼光谱

采用循环伏安法处理Ag电极,得到活化的具有表面增强拉曼光谱(SERS)效应的粗糙Ag表面,进一步采用激光拉曼光谱探讨了2-巯基苯并咪唑(MBI)在其表面的自组装分子层的吸附特性。实验表明,在活性Ag表面的MBI自组装分子层能够产生理想的SERS效应,其强度随探针分子MBI浓度的增加先提高后减弱,达到一定浓度时因受其空间位阻等因素的影响,增强效应减弱。MBI在1×10^-6 mol·L^-1 浓度时增强效果最大。拉曼增强效应随着体系酸度的变化有着明显不同,在强酸性条件下的增强效应明显优于中性和碱性条件。MBI分子存在两种不同的异构体和在不同酸度下存在3种不同的存在形态,并形成动态平衡。pH <2时,MBI分子主要以硫酮式MBI⁺存在,并以巯基上的S:与活性Ag以配位方式吸附成键,其整个大π键平面垂直地吸附于Ag表面,产生相对较大的SERS信号。pH >2时,由于硫酮式和硫醇式与活性Ag的键合方式和能力不同,硫醇式上的S与Ag以S-Ag共价方式同时双键侧上的N以配位方式协同参与吸附成键,比硫酮式MBI⁺的单纯配位吸附要强,因而形成了竞争吸附,表现为SERS在pH=2~3.7之间的急剧下降。MBI硫醇式由于以S-Ag、N-Ag键的协同吸附,形成了倾斜侧卧式垂直吸附,而使拉曼增强效应相对减弱。     

杀线威在Fe_3O_4/Ag纳米磁粒上的吸附及表面增强拉曼光谱研究

采用共沉淀法合成了Fe_3O_4磁性纳米颗粒,进一步以柠檬酸三钠还原法制备出了具有SERS活性的Fe_3O_4/Ag磁性包覆修饰材料,用紫外可见吸收光谱、能谱及透射电镜对结构与形貌进行表征,发现所制备的Fe_3O_4/Ag纳米材料粒径约为30~60nm,形貌规整接近球形,经测试Fe_3O_4/Ag材料很容易被磁铁收集,能够满足分散萃取再收集的需要。根据密度泛函理论(DFT)对杀线威(Oxamyl)、Oxamyl-Ag和OxamylAg4进行了理论结构优化计算,得到了杀线威的理论拉曼光谱和与Ag表面增强拉曼光谱及其谱峰的归属,结合表面增强拉曼光谱(SERS)测定,研究了杀线威在Fe_3O_4/Ag表面的吸附行为和增强效应,测算得到杀线威在Fe_3O_4/Ag表面上的增强因子为2.08×105。研究表明:理论计算的杀线威拉曼光谱与测定的拉曼光谱具有较好的一致性,DFT理论计算中发现研究分子与活性Ag原子作用越多,与实测值常规拉曼NRS越接近;杀线威以双键侧N原子和S原子与Fe_3O_4/Ag表面吸附作用为主;双键侧N优先与Ag吸附成键后,整个分子靠近Ag表面,最终使得双键侧N原子与S原子共同吸附在Ag表面;Fe_3O_4/Ag磁性纳米复合材料具有显著的富集吸附和拉曼增强作用;可利用其作为拉曼基底,以实现SERS光谱法对杀线威农残的快速分析检测。     

Surface‐enhanced Raman scattering‐based approach for DNA detection at low concentrations via polyvinyl alcohol‐protected silver grasslike patterns

A simple method is demonstrated to detect DNA at low concentrations on the basis of surface‐enhanced Raman scattering (SERS) via polyvinyl alcohol‐protected silver grasslike patterns (PVA‐Ag GPs) grown on the surface of the common Al substrate. By the SERS measurements of sodium citrate and thymine, the PVA‐Ag GPs are shown to be an excellent SERS substrate with good activity, stability and reproducibility. With the use of the tested molecule of thymine, the enhancement factor of the PVA‐Ag GPs is up to ~1.4 × 10⁸. The PVA‐Ag GPs are also shown to be an excellent SERS substrate with good biocompatibility for DNA detection, and the detection limit is down to ~10⁻⁵ mg/g. Meanwhile, the assignations of the Raman bands and the adsorption behaviors of the DNA molecules are also analyzed. In this work, the geometry optimization and the wavenumber analysis of adenine–Ag and guanine–Ag complexes for the ground states are performed using density functional theory, B3LYP functional and the LanL2DZ basis set. The transition energies and the oscillator strengths of adenine–Ag and guanine–Ag for the lowest six singlet excited states were calculated by using the time‐dependent density functional theory method with the same functional and basis set. The results show that the charge transfer in the adenine–Ag and guanine–Ag complexes should be the chemical factor for the SERS of the DNA molecules. Lastly, this method may be employed in large‐scale preparation of substrates that have been widely applied in the Raman analysis of DNA because the fabrication process is simple and inexpensive. Copyright © 2011 John Wiley & Sons, Ltd.     

Surface enhanced Raman scattering of water on an Ag electrode

Surface enhanced Raman scattering of adsorbates on an Ag electrode in various electrolytes (e.g., 0.1–1.0 M KF, KCl, KBr, KI, K₃PO₄, and NaN₃) has been investigated in an effort to elucidate the mechanism of the enhancement of water compared to that for other adsorbates. (It is well known, for example, that pyridine exhibits large enhancement in 0.1 M KCl while SERS from water is not detectable unless the salt concentration is raised to almost 1 M.) Use of an optical multichannel analyzer allowed rapid recording of Raman spectra, and SERS intensities of adsorbates could therefore be monitored simultaneously during a continuous oxidation-reduction cycle. Potential dependencies of SERS intensities when the electrode potential is cycled in a non-faradiac potential range immediately following oxidation and reduction indicate that adatoms are partially responsible for the Raman enhancement. Furthermore, the anions in the electrolyte play an important role in stabilizing these “active sites.” For this reason, the degree of enhancement is influenced by the solubility of the Ag compound formed during oxidation and the specific adsorption of the anions to the Ag surface. Preferential alignment of H₂O molecules with their oxygen ends facing the surface at positive potentials, the tendency of anions in the electrolyte to disrupt hydrogen bonding with the water network, and the weak hydrogen bonding of H₂O with the anions give rise to a SERS lineshape from adsorbed H₂O molecules which is narrower than, and thus distinguishable from, the Raman line of bulk water. Thus, the degree to which the particular anions in the electrolyte disrupt hydrogen bonding among water molecules and reform hydrogen bonding between the anions and H₂O molecules influences the SERS lineshape and the apparent enhancement of the H₂ Raman emission.     

2-噻吩甲酸在Fe3O4@Ag基底上的吸附及表面增强拉曼光谱

采用共沉淀法合成Fe₃O₄纳米颗粒,再以柠檬酸三钠还原AgNO₃获得了具有SERS活性的Fe₃O₄@Ag磁性纳米复合材料。基于密度泛函理论(DFT)的量子化学计算方法和表面增强拉曼光谱(SERS)技术,从理论计算和实验测定表征探讨了2-噻吩甲酸(2-TCA)在Fe₃O₄@Ag表面的吸附行为和增强效应。结果表明:理论计算得到的拉曼光谱与实际测得的常规拉曼光谱基本一致,而在DFT理论计算中所键连的Ag原子数越多,与实测值就越接近。溶液的浓度和pH对拉曼增强效果有很大的影响,当溶液的pH=3且浓度为1×10^-4 mol·L^-1时有最大拉曼增强效应。峰强随2-TCA浓度的增加呈现先增大后减小的趋势,浓度过大会导致大量2-TCA分子吸附聚集在Ag表面形成局部"拥堵",阻碍了激发光尤其是光谱信号的散射通过,从而减弱了拉曼增强效应。pH的变化使溶液中2-TCA分子形态发生改变,结构形态不同,其在Ag表面的吸附方式也不同。中性C₄H₃SCOOH分子以环上S:形式垂直吸附键合在Ag表面,形成S—Ag配位键而产生SERS光谱。-1价C₄H₃SCOO^-离子以S—Ag配位和O—Ag共价"双键合"侧卧方式共同吸附在Ag表面而产生SERS光谱。在Ag表面,以单独S—Ag配位键吸附或键合的能力比S—Ag配位和O—Ag共价共同吸附方式要弱,但其产生的SERS信号更强,故2-TCA中性分子比2-TCA^-离子更有利于SERS的产生。随着pH值的增加,溶液中的2-TCA由中性分子逐渐转化为-1价的C₄H₃SCOO^-离子,因而在pH>3以后,拉曼增强效应逐步减弱。     

菜粉蝶颗粒体病毒包涵体在银胶中的表面增强拉曼光谱研究

本文讨论了菜粉蝶(preris rtpae)颗粒体病毒(简称 PrGV )包涵体在银胶中的表面增强拉曼光谱。PrGV 包涵体的 SERS 谱与其 RS 谱之间存在一定对应关系。PrGV 包涵体蛋白分子通过羧基和氨基基团吸附于银粒子表面,并构成阴离子形式(NU_2RCOO~-)存在于溶液中。PrGV 在银胶中的表面增强的增强机制属于短程作用。PrGV 包涵体与银胶表面的吸附主要是化学吸附。     

Hydrogen bonding and aromaticity in the guanine–cytosine base pair interacting with metal cations (M = Cu+, Ca2+ and Cu2+)

The influence of metal cations (M?=?Cu⁺, Ca²⁺ and Cu²⁺) coordinated to the N₇ of guanine on hydrogen bonding and aromaticity of the guanine–cytosine base pair has been analysed with the help of delocalization indices using the B3LYP functional. Our analysis shows that the strengthening of the N₁···N₃ and N₂···O₂ hydrogen bonds and the weakening of the O₆···N₄ hydrogen bond is mainly caused by the modification of donor–acceptor (covalent) interactions rather than to a significant change of electrostatic interactions. On the other hand, the increase of the aromaticity of the guanine and cytosine six-membered rings because of the interaction with Cu⁺ and Ca²⁺ is attributed to the strengthening of hydrogen bonding in the guanine–cytosine pair. The observed reduction of aromaticity in the five- and six-membered rings of guanine due to ionization or interaction with Cu²⁺ is caused by the oxidation process that removes a?π?electron disrupting the?π?electron distribution.     

胸腺嘧啶单体及环丁烷型胸腺嘧啶二聚体的表面增强拉曼散射

采用DFT-B3LYP方法,6-311G(d,p)(C,H,O原子)和lanl2dz（Ag原子）基组计算了胸腺嘧啶单体（Th）和DNA光损伤产物—环丁烷型胸腺嘧啶二聚体（Th2）吸附在Ag纳米粒子上形成复合物的结构和表面增强拉曼散射（SERS）。结果显示, Ag纳米粒子在胸腺嘧啶单体（Th）和环丁烷型胸腺嘧啶二聚体中最有利的吸附位点是O7位,相比于单个分子,复合物Th-Ag,Th2-Ag的结构和光谱发生了变化。对胸腺嘧啶单体分子,其SERS的增强因子为10,主要由N-H伸缩振动引起;复合物Th2-Ag中, SERS增强了大约18倍,主要由C2=O的伸缩振动引起,此增强机理属于极化率变化产生的静化学增强。