乙腈溶液中银电极的表面增强拉曼光谱研究

利用共焦显微拉曼系统研究了非水体系0.1mol·L^-1LiClO4/CH3CN溶液中,乙腈分子在粗糙银和金电极表面的吸附和解离行为。结果表明非水体系中乙腈可在银、金表面发生还原反应,产物CN^-离子与电极表面作用形成的表面配合物可以较宽的电位区间吸附于电极表面。溶液中的微量水、激光照射以及电极电位均对该反应有较大的影响。通过拉曼谱图的比较,得出乙腈分子解离出的CN^-在金电极表面比在银电极表面有更强的吸附作用。     

三元水溶液体系中氢键作用与分子结构的拉曼光谱研究

采用拉曼光谱研究了水-乙腈-二甲基亚砜三元水溶液体系中氢键作用对分子结构的影响.结果表明,在三元水溶液中乙腈C≡N键的电子云向碳原子发生偏移,二甲基亚砜中S=O双键的电子云向硫原子发生偏移;在三元体系中乙腈和二甲基亚砜与水形成氢键时存在明显的竞争关系,出现乙腈分子和二甲基亚砜分子共用1个水分子形成复合物的情况,并且随着水含量的增加,共用水分子的情况逐渐消失.     

非水反相微乳的加溶与电导性质研究

研究了若干非水极性溶剂（甲酰胺、二甲基亚砜和乙腈）及其与水的混合物/AOT/正庚烷反相微乳体系的加溶性质及其电导行为.结果表明，在AOT反相微乳中，非水极性溶剂的最大加溶量均远小于水的加溶量.其最大加溶量顺序为二甲基亚砜< 甲酰胺< 乙腈< 水.甲酰胺和乙腈与水的加溶相互抵制，而水在一定范围内可促进二甲基亚砜的加溶.非水反相微乳的电导率随加溶量的变化规律与含水反相微乳体系类同，但到达电导率极大值和出现渗滤时的加溶量明显比含水反相微乳 体系的要小.     

咪唑对锌缓蚀机理的表面增强拉曼光谱研究

利用电化学现场表面增强拉曼光谱技术(SERS)研究了咪唑在锌表面的成膜和缓蚀行为, 讨论了电位和pH值对咪唑分子和金属表面作用的影响. 锌电极上的表面拉曼光谱研究结果表明, 中性溶液中咪唑对锌的缓蚀作用明显, 它通过氮端垂直吸附在锌表面, 从而阻止锌的腐蚀, 其吸附取向不随电位的变化而改变; 在碱性溶液中咪唑和锌的作用较弱, 而且电位变化可以使其吸附取向发生改变, 在较正电位下咪唑以氮端垂直吸附, 在较负电位下以咪唑环倾斜吸附.     

离子液体中Fe电极界面结构的SERS光谱研究

采用高灵敏度的表面增强拉曼光谱(SERS)技术,结合不同长度的探针分子,通过电化学调控研究了Fe电极在离子液体中的表面增强因子、零电荷电位、界面吸附及界面双电层结构.利用壳层隔绝纳米粒子增强拉曼光谱(SHINERS)技术提高表面吸附物种的拉曼信号,降低高浓度本体的信号干扰,研究了1-丁基-3-甲基咪唑四氟硼酸盐([BMIm]BF4)离子液体本身在Au@SiO2修饰的Fe电极表面的吸附行为.结果表明,[BMIm]BF4在Au@SiO2修饰的Fe电极表面的吸附行为随电位变化而变化.在-1.3 V以正区间,咪唑阳离子以垂直吸附为主,随电位负移逐渐倾斜甚至平躺吸附于电极表面;当电位负至-2.3 V,咪唑阳离子还原成卡宾.再分别以不同分子长度的硫氰根(SCN-)和4-氰基吡啶(4-CNPy)为探针分子,发现SCN-在[BMIm]BF4中以N端吸附在纯Fe电极上,三键频率随电位变化的速率,即Stark系数为17 cm-1/V;4-CNPy以吡啶环上的N垂直吸附于Fe电极上,频率保持不变,即Stark系数接近零.以上结果表明,在离子液体中电极界面双电层与水体系的差别较大,电位主要分布在电极紧密层中,几乎无分散层存在.此外,还计算了[BMIm]BF4中Fe电极的增强因子约为1.5×102.     

镍电极表面吸附的苯并咪唑电化学SERS研究

利用电化学循环伏安和极化曲线,考察了镍电极在不同浓度苯并咪唑(BMIH)-乙腈体系的缓蚀效果.结果表明,随着缓蚀剂BIMH浓度的增加,其氧化电位正移,且氧化电流降低,腐蚀电位正移.调制电位下测试镍电极表面BMIH吸附的现场表面增强拉曼光谱.随电位正移,BIMH可在镍电极表面吸附成膜,与金属镍生成配合物,阻止镍电极的腐蚀.并考察了不同浓度BIMH的成膜行为.结果发现,0.001 mol·L-1BIMH即可在镍电极表面成膜,这表明非水乙腈体系的镍表面,BMIH有较佳的缓蚀效果.     

电化学方法和表面增强拉曼光谱技术研究钴电极表面咪唑的吸附和缓蚀行为

利用电化学和表面增强拉曼光谱方法研究了咪唑和钴电极的相互作用. 分析并指认了不同电极电位下咪唑溶液中钴电极上的表面增强拉曼光谱(SERS), 发现随电极电位的变化, 在钴电极表面存在三种表面物种并且可以在一定程度上相互转化. 在较负电位(&#8722;1.2~&#8722;0.9 V)区间, 咪唑在钴电极表面以吸附物种为主, 随电位正移, 吸附取向由通过吡啶N垂直吸附逐渐向C2=N3双键倾斜; 在较正电位区间(&#8722;0.8~&#8722;0.7 V)内, 吸附咪唑的信号逐渐减弱乃至消失, 而钴和咪唑的络合物信号逐渐增强; 开路电位(&#8722;0.6 V)下出现很强的钴的氧化物谱峰. 同时, 文中比较了钴电极表面在空白溶液和加入咪唑后的溶液中的极化曲线, 发现咪唑对钴电极的缓蚀作用较为明显. 该研究结果表明, 联合表面增强拉曼光谱技术和电化学方法使得人们可以从分子水平上了解表面物种和电极表面间复杂的相互作用.     

咪唑啉酰胺在电偶电极表面的吸附行为

采用原子力显微镜技术研究了有机阳离子缓蚀剂(咪唑啉酰胺)在电偶电极表面的吸附行为, 并探讨了其腐蚀抑制机理. 结果表明, 金属表面的过剩电荷较大地影响缓蚀剂分子的吸附行为. 在1%的NaCl溶液中, 碳钢电极表面带有过剩的负电荷；不锈钢电极表面带有过剩的正电荷；碳钢电极和不锈钢电极耦合后, 其表面分别带有过剩的正电荷和负电荷. 在耦合前阳离子缓蚀剂分子仅吸附在碳钢表面, 耦合后缓蚀剂分子在偶对的阴极(不锈钢)和阳极(碳钢)表面均有吸附, 但缓蚀剂分子在碳钢表面的吸附强度和覆盖度较之耦合前降低, 缓蚀剂的腐蚀抑制能力减弱.     

苯硫酚及其衍生物在银电极表面的吸附取向

采用表面增强拉曼光谱技术研究了苯硫酚及其功能衍生物，对巯基苯胺和对苯硫酚在粗糙银电极上的吸附取向特征。结果表明：虽然3种分子的结构类似，但对位取代基直接影响各分子在电极上的吸附取向。3种分子都通过硫原子与银电极形成S-Ag键吸附在电极表面。苯硫酚采用倾斜的方式吸附，使得苯环与基底间表现一定程度的相互作用；吸附的对巯基苯胺则因质子化氨基间的静电相互作用而完全垂直于电极表面；而对苯硫酚则采用平躺于电极表面的方式吸附，致使苯环π体系与基底银之间具有较强的相互作用。     

和频振动光谱研究多晶金电极/溶液界面乙腈分子取向的flip-flop行为

应用和频振动光谱研究乙腈/金电极界面吸附,观测到乙腈的甲基振动峰强度随电极电势而变化.当电极电势越过零电荷电势(pzc)时,甲基振动峰符号发生反转,这意味着该基团取向发生反转(flip-flop).由此而推断乙腈分子在金电极界面的吸附构型.即在零电荷电势下,电极界面吸附的乙腈分子构型为甲基靠近电极表面而腈基远离电极表面...     

Investigations on Substituent and Solvent Effects of Solvolysis Reactions. VIII. The Influence of Water and Nonaqueous Solvents on the Imidazolysis of 4-Nitrophenyl Acetate

The aminolysis reaction of 4-nitrophenyl acetate with imidazole was investigated in water, acetonitrile, propylene carbonate, and 1,4-dioxane at different temperatures. the observed rates can be evaluated with the help of a reaction mechanism consisting of two competitive reaction paths; the first is the bimolecular nucleophilic substitution of the phenol moiety by imidazole; the second path is performed via general base catalysis by a second imidazole molecule. The rate constants of the bimolecular reaction are quantitatively correlated with the four-parameter Taft–Kamlet equation for solvent effects on chemical reactions. A qualitative interpretation of the data shows that the two reaction paths are influenced to the same extent by the solvent.     

配体结构对含2-甲基咪唑及N-乙基咪唑的NAMI衍生物水解及溶液稳定性的影响

制备并用UV、循环伏安(CV)和NMR法研究了NAMI(新抗肿瘤转移抑制剂,trans-[RuCl4(DMSO)(imidazole)]Na·2DMSO)衍生物trans-[RuCl4(DMSO)(2-MeIm)]Na·2DMSO(2-MeIm=2-甲基咪唑,化合物1)和trans-[RuCl4(DMSO)-(N-EtIm)]Na·2DMSO(N-EtIm=N-乙基咪唑,化合物2)的水解机理-动力学、溶液稳定性和电化学性质.化合物1和化合物2与NAMI相似,在pH 7.40的缓冲溶液中发生两步脱氯水解反应(I氯水解及II氯水解)(分步反应);在酸性溶液(pH 5.00)中脱DMSO水解.通过线性拟合得到各水解反应速率常数kobs及半衰期t1/2.结果表明化合物在酸性溶液中的稳定性相对较高.在NAMI衍生物咪唑环的N位引入乙基比在2位引入甲基生成的化合物稳定.含氮配体相同时,NAMI-A(新抗肿瘤转移抑制剂,A:该系列中的第一个化合物,trans-[RuCl4(DMSO)(imidazole)][Himidazole])衍生物略比相应的NAMI衍生物稳定.     

Ion-exclusion/adsorption chromatography of dimethylsulfoxide and its derivatives for the evaluation to quality-test of TiO(2)-photocatalyst in water

Ion-exclusion/adsorption chromatography of dimethylsulfoxide (DMSO) and its derivatives, i.e., methanesulfinic acid (MSI), methanesulfonic acid (MSA) and sulfuric acid (SA), was developed in order to clear the decomposition mechanism of DMSO on quality-test of TiO₂-photocatalyst in water. The separation was achieved by the adsorption effect for DMSO and ion-exclusion effect for MSI, MSA and SA under optimum conditions, using a weakly acidic cation-exchange resin column with 20 mM succinic acid as the eluent. In this system, DMSO and MSI with UV at 195 nm and MSA and SA with conductivity detection were consecutively determined by single injection and single separation column. This method was used to monitor the artificial decomposition of DMSO induced by a photocatalyst. The concentration of DMSO by active oxygens (e.g., OH radical) generated from surface of photocatalyst was found to be decreased through the stoichiometric reaction in the order of MSI, MSA and SA.     

Solvent effects on interfacial electron transfer from Ru(4,4'-dicarboxylic acid-2,2'-bipyridine)2(NCS)2 to nanoparticulate TiO2: spectroscopy and solar photoconversion

Resonance Raman spectra are reported for Ru(4,4'-dicarboxylic acid-2,2'-bipyridine)2(NCS)2 (commonly called "N3") in ethanol solution and adsorbed on nanoparticulate colloidal TiO2 in ethanol (EtOH) and in acetonitrile (ACN), at wavelengths within the visible absorption band of the dye. Raman cross sections of free N3 in EtOH are found to be similar to those of N3 adsorbed on colloidal TiO2 in EtOH, and are generally lower than those of N3 on TiO2 in ACN. Strong electronic coupling mediated by surface states results in red-shifted absorption spectra and enhanced Raman signals for N3 adsorbed on nanocolloidal TiO2 in ACN compared to EtOH. In contrast, the absorption spectrum of N3 on nanocrystalline TiO2 in contact with solvent is similar for ACN and EtOH. Wavelength-dependent depolarization ratios for N3 Raman bands of both free and adsorbed N3 reveal resonance enhancement via two or more excited electronic states. Luminescence spectra of N3 adsorbed on nanocrystalline films of TiO2 and ZrO2 in contact with solvent reveal that the quantum yield of electron injection phi(ET) into TiO2 decreases in the order ACN > EtOH > DMSO. Dye-sensitized solar cells were fabricated with N3 adsorbed on nanocrystalline films of TiO2 in contact with ACN, EtOH, and DMSO solutions containing LiI/LiI3 electrolyte. Photoconversion efficiencies eta were found to be 2.6% in ACN, 1.3% in DMSO, and 0.84% in EtOH. Higher short circuit currents are found in cells using ACN, while the maximum voltage is found to be largest in DMSO. It is concluded that the increased photocurrent and quantum yield of interfacial electron transfer in acetonitrile as compared to ethanol and DMSO is primarily the result of faster electron injection of N3 when adsorbed on TiO2 in the presence of ACN as opposed to EtOH or DMSO.     

Kinetics of two pathways in peroxyoxalate chemiluminescence

It has been shown that 1,1'-oxalyldiimidazole (ODI) is formed as an intermediate in the imidazole-catalyzed reaction of oxalate esters with hydrogen peroxide. Therefore, the kinetics of the chemiluminescence reaction of 1,1'-oxalyldiimidazole (ODI) with hydrogen peroxide in the presence of a fluorophore was investigated in order to further elucidate the mechanism of the peroxyoxalate chemiluminescence reaction. The effects of concentrations of ODI, hydrogen peroxide, imidazole (ImH), the general-base catalysts lutidine and collidine, and temperature on the chemiluminescence profile and relative quantum efficiency in the solvent acetonitrile were determined using the stopped-flow technique. Pseudo-first-order rate constant measurements were made for concentrations of either H2O2 or ODI in large excess. All of the reaction kinetics are consistent with a mechanism in which the reaction is initiated by a base-catalyzed substitution of hydrogen peroxide for imidazole in ODI to form an imidazoyl peracid (Im(CO)2OOH). In the presence of a large excess of H2O2, this intermediate rapidly decays with both a zero- and first-order dependence on the H2O2 concentration. It is proposed that the zero-order process reflects a cyclization of this intermediate to form a species capable of exciting a fluorophore via the "chemically initiated electron exchange mechanism" (CIEEL), while the first-order process results from the substitution of an additional molecule of hydrogen peroxide to the imidazoyl peracid to form dihydroperoxyoxalate, reducing the observed quantum yield. Under conditions of a large excess of ODI, the reaction is more than 1 order of magnitude more efficient at producing light, and the quantum yield increases linearly with increasing ODI concentration. Again, it is proposed that the slow initiating step of the reaction involves the substitution of H2O2 for imidazole to form the imidazoyl peracid. This intermediate may decay by either cyclization or by reaction with another ODI molecule to form a cyclic peroxide that is much more efficient at energy transfer with the fluorophore. The reaction kinetics clearly distinguishes two separate pathways for the chemiluminescent reaction.     

A DFT study of acetonitrile adsorption and decomposition on the TiO2 (110) surface

The adsorption and decomposition of acetonitrile on the TiO₂ (110) surface have been investigated with first principles calculations. Our results reveal that both C?N and C? C bonds of acetonitrile become weakened after adsorption. Acetonitrile behaves as an electron donor, and electrons transfer from acetonitrile to substrate is obvious. The reaction mechanism of further decomposition of acetonitrile on TiO₂ (110) surface is also investigated, and the result shows that acetonitrile can decompose into CH₃ and CN fragments and form OCH₃ and NCO groups on the TiO₂ (110) surface, which consists with the experimental results. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

Poly(N-vinylimidazole/ethylene glycol dimethacrylate) for the purification and isolation of phenolic acids

In this study we report the novel polymeric resin poly(N-vinyl imidazole/ethylene glycol dimethacrylate) for the purification and isolation of phenolic acids. The monomer to crosslinker ratio and the porogen composition were optimized for isolating phenolic acids diluted in acetonitrile at normal phase chromatography conditions, first. Acetonitrile serves as polar, aprotic solvent, dissolving phenolic acids but not interrupting interactions with the stationary phase due to the approved Hansen solubility parameters. The optimized resin demonstrated high loading capacities and adsorption abilities particularly for phenolic acids in both, acetonitrile and aqueous solutions. The adsorption behavior of aqueous standards can be attributed to ion exchange effects due to electrostatic interactions between protonated imidazole residues and deprotonated phenolic acids. Furthermore, adsorption experiments and subsequent curve fittings provide information of maximum loading capacities of single standards according to the Langmuir adsorption model. Recovery studies of the optimized polymer in the normal-phase and ion-exchange mode illustrate the powerful isolation properties for phenolic acids and are comparable or even better than typical, commercially available solid phase extraction materials. In order to prove the applicability, a highly complex extract of rosemary leaves was purified by poly(N-vinyl imidazole/ethylene glycol dimethacrylate) and the isolated compounds were identified using UHPLC–qTOF-MS.     

Analyzing the Vibrational Signatures of Thiophenol Adsorbed on Small Gold Clusters by DFT Calculations

Using density functional theory, we calculate the IR and Raman signatures of the thiophenol (TP) molecule adsorbed on gold clusters by mimicking the different types of adsorption sites, and we analyze these signatures by using advanced tools implemented into the pyvib2 program. First, we follow the evolution of the vibrational normal modes from the isolated TP molecule to those of TP adsorbed on different clusters to highlight the influence of the site of adsorption on the vibrational motions. The use of the overlap matrix between the modes enables mode permutations, mode mixings, and mode splittings to be highlighted, all of which depend not only on the adsorption but also on the type of cluster and its symmetry. Second, the IR and Raman signatures were analyzed by using group coupling matrices and atomic contribution patterns based on the Hug decomposition scheme. Key results include 1) the fact that Raman spectroscopy is more sensitive than IR spectroscopy with respect to the nature of the coordination site, 2) an IR criterion that distinguishes between on‐top coordination (onefold coordinated) with respect to the bridge (twofold coordinated) and hexagonal close‐packed hollow site coordination (threefold coordinated), and 3) the best agreement to the experimental Raman spectrum with regard to signatures in the 500 to 1200 cm^?1 region is obtained for bridged, twofold coordination.     

Adsorption mechanism and acidic behavior of naphthazarin on Ag nanoparticles studied by Raman spectroscopy

Surface-enhanced Raman scattering (SERS) spectroscopy is applied in this work to the study of the adsorption of naphthazarin (NZ) on Ag nanoparticles. Spectra recorded at different excitation wavelengths and pHs revealed that this molecule is adsorbed on the metal through several mechanisms. Two main types of adsorbed molecules can be identified that correspond to neutral and ionized NZ, which may be physisorbed or chemisorbed on the metal. The existence of these different forms can be due to different binding sites on the surface or to the formation of a multilayer architecture on the metal surface giving rise to different adsorbate states. Although the amount of the ionized molecule attached on the surface is higher at neutral pH, the neutral molecule may also exist even at very high pH. The amount of neutral NZ increases with the time and also as the NZ concentration is raised or as the dimethylsulfoxide (DMSO) concentration existing in the medium is increased.