维生素K3电化学反应机理的红外光谱电化学研究

用循环信安法及现场红外光谱电化学法研究了维生素Ｋ３在铂电极上,弱碱性水溶液介质中的电化学反应机理。循环伏安法实验结果显示ＶＫ３的电反应为两步电子准可逆电极过程,现场光谱电化学实验结果则从基团特征吸收频率的变化表明了ＶＫ３的电化学还原和氧化经历了从萘醌到萘酚的互变过程。据此进一步证实了ＶＫ３由萘醌到酚的电化学反应机理。     

细胞色素c在咔唑修饰的金电极上的直接电化学

在生物体内,细胞色素c是一种电子载体,它能进行可逆的氧化还原反应,但在金属电极上的电化学反应却不可逆。1977年,Hill研究组发现,在4,4′-联吡啶存在时,细胞色素c在金电极上能进行准可逆的电化学反应。4,4′-联吡啶在细胞色素c电化学反应的过程中不起氧化还原反应而被称为促进剂。Hill等对50多种有机化合物的促进作用进行评价后提出,能加速细胞色素c电化学反应速率的促进剂分子至少应具有两个功能团。表面增强拉曼光     

NanoTiO2-CNT复合膜电极在DMF溶液中对糠醛的异相电催化还原

通过在乙醇中电化学溶解Ti金属阳极合成前驱体Ti(OEt)4和溶胶-凝胶法在Ti表面修饰一层纳米TiO2-碳纳米管(nanoTiO2-CNT)复合膜, 采用循环伏安和电解合成法研究了nanoTiO2-CNT复合膜电极在N, N-二甲基甲酰胺(DMF)中的氧化还原行为以及对糠醛(furfural)还原的电催化活性. 结果发现, nanoTiO2-CNT电极在阴极扫描时有两对氧化还原峰, 可逆半波电位E r1/2 分别为－1.27 V和－2.44 V(vs SCE, 扫描速度100 mV•s-1), 分别对应于TiO2/Ti2O3氧化还原电对的可逆电极过程和TiO2/Ti(OH)3电对的准可逆电极过程；在DMF电解液中nanoTiO2-CNT复合膜中的Ti(IV)/Ti(III)氧化还原电对作为媒质间接电还原糠醛为糠醇, 反应机理为电化学偶联随后化学催化反应(EC′)机理.     

双功能有机物修饰电极的修饰层结构对催化细胞色素C的电极反应的影响

用光谱电化学法研究了双功能有机物健那绿的电化学性质。在铂电极上,健那绿发生四步单电子传递过程。在健那绿修饰电极上细胞色素C的直接、非均相电子传递反应是准可逆氧化还原反应,电极反应速率常数K_s=4.17×10~(-4)cm/s。电极表面的修饰方法不同对细胞色素C的电极反应有很大影响。     

核黄素在玻碳电极上的电化学行为

用电位扫描、旋转环盘电极和微分电容等方法研究了核黄素在玻碳电极上的电化学行为。在ｐＨ〈６的介质中，观察到一个典型的氧化还原波，它是可逆的二电子反应，其还原产物ＲＦＨ２在电极上的吸附为弱吸附，溶出性能良好，在６〈ｐＨ〈１０的介质中，出现两个分离但仍有部分重叠的氧化还原波，相应于两步单电子反应，还原所生成的ＲＦＨ和ＲＦＨ２发生吸附，很难溶出。在ｐＨ〉１０的介质中，仍然出现两个分离但有部分重叠的氧化还原     

肌红蛋白在灿烂甲酚蓝修饰电极上的可逆电子传递反应

利用循环电位吸收法和电位阶跃计时吸收法在薄层电解池中研究了肌红蛋白在灿烂甲酚蓝(BCB)修饰电极上和BCB溶液中的电化学行为。实验表明肌红蛋白可以发生可逆的还原和氧化反应,完全还原和氧化分别需要20和100s, 氧化还原反应的标准速率常数被估算为5.6×10^-^4cm·s^-^1, 并且稳定性很好, 没有蛋白质变性反应发生。用光谱电化学方法测得该反应的标准电极电位和电子转移数与肌红蛋白相符。光电子能谱实验表明肌红蛋白没有吸附在BCB修饰电极上, 对BCB修饰电极促进肌红蛋白的电子转移机理作了初步探讨。     

酸性介质中碘离子在铂电极上的电化学氧化行为

采用循环伏安法研究了酸性介质中碘离子在铂电极上不同电位区间, 不同酸度下的电化学反应行为. 结果表明, 当极化电位较低(小于0.6 V(vs Hg/Hg2SO4))时, 碘离子在铂电极上发生2I--2e→I2电氧化反应, 反应产物通过I2+I-=I-3被进一步溶解, 整个反应属于E-C(electrochemical-chemical)模式. 电氧化过程中可以形成碘膜, 其也可以被碘离子溶解. 当极化电位升高至0.6 V(vs Hg/Hg2SO4)或以上时, 碘离子会直接电氧化为高价态碘化合物, I-+3H2O→IO-3+6H++6e, 而析出的碘膜并不发生再氧化反应; 在电化学还原过程中, 出现了两个还原峰, 分别对应于I2、I-3的还原反应; 在无碘膜时, 碘离子电氧化过程受溶液中碘离子的液相扩散步骤控制; 碘膜形成后, 主要受碘膜中碘离子的固相扩散控制; 酸度对于碘离子的电化学氧化过程有很大的影响, 其线性极化曲线的起峰电位及电流峰值电位均随酸浓度升高而负移.     

二茂铁衍生物光学特性的氧化还原开关效应

设计合成了三种具有推拉电子取代基的二茂铁衍生物D-Fc-R(1), D-Fe-A1(2), [D-Fc-A2(3)N-C6H4-CH=CH, R :CH2OH, A1 : CHO, A2 : CH=C(CN)2], 并对其循环伏安及光谱电化学行为进行了研究。三种衍生物均出现两个氧化还原电时,1的两个电对均可逆, 单扫第一电对, 2的第一电对是可逆, 3的第一电对是准可逆, D-Fc^+-R在613nm, D-Fc^+-A1在705nm有强LMCT带, 具有良好的光学特性氧化还原开关效应。     

胆红素胆绿素在铂电极上氧化还原反应的现场光谱电化学研究

本文采用现场光谱电化学技术研究了胆红素(BR Ⅳα)、胆绿素(BV Ⅳα)及其氧化产物胆汁红紫素(Bi-Pu)在铂电极上的电氧化还原行为,并着重对上述过程的动力学进行了探讨。结果表明,在洁净的铂电极上,上述胆汁色素可通过控制电位实现Ⅳ构成的反应循环中,Ⅰ,Ⅱ可达到准可逆电子转移反应,式量非均相速率常数=1.5×10~(-4)cm·s~(-1),而Ⅲ,Ⅳ的氧化还原则为不可逆,=4.8×10~(-5)cm·s~(-1)。     

质谱电喷雾离子源中电化学与电晕放电氧化还原反应的研究进展

质谱电喷雾离子化过程中包含两类氧化还原反应:电化学氧化还原和电晕放电氧化还原。一方面,这两类反应干扰谱图解析、降低分析物的检测灵敏度;另一方面,利用氧化还原的特性可发展新型离子源,提高电喷雾离子化过程中难离子化化合物的离子化效率,研究蛋白质相互作用等。该文系统地介绍了国内外对于电化学氧化还原反应和电晕放电氧化还原反应的最近研究进展,主要包括此两类反应的弊端、应用价值,以及控制两类反应的方法。最后总结了区分两种反应的方法,并对电喷雾离子源的发展进行了展望。     

玻碳电极上多巴胺的氧化还原机理

用电化学方法和光谱电化学方法详细研究了多巴胺(DA)在玻碳(GC)电极表面的反应机理.结果表明DA的电氧化是一个单电子转移过程而不是一个双电子转移过程,在此过程中有半醌自由基中间体存在.用多种电化学手段测定了电极反应动力学参数,提出了新的电极反应机理.     

细胞色素C在阴离子修饰的盐桥支撑双层类脂膜上的电化学行为及其应用

采用循环伏安法研究了细胞色素C在月桂酸阴离子修饰的盐桥支撑双层类脂膜上的氧化还原反应;对盐桥支撑双层类脂膜的特性、细胞色素C的电化学反应动力学以及有关影响细胞色素C循环伏安行为各种因素进行了详细探讨;并对用该双层类脂膜体系电化学测定细胞色素C进行了初步尝试。     

STUDY OF ELECTROCHEMISTRY OF TETRANUCLEAR MOLYB-DENUM CLUSTER COMPOUND [Mo_4S_4(μ-dtp)_2(dtp)_4]

<正> The electrochemical behavior of tetranuclear molybdenum cluster [Mo4S4 (μ-dtp)2 (dtp)43 (1) (dtp = S2P (OEt)2) has been investigated by cyclic voltammetry, potentiotatic polarization measurement, controlled potential coulometry and pulse polarography. It is demonstrated that the compound undergoes two consecutive near reversible one-electron reductions at 0. 01V and -0. 77V , respectively and a near reversible one-electron oxidation at 1. 01V with scan rates from 25mV/sec to 1V/sec in cyclic voltammetric measurements. The cluster compound displays three redox processes, indicating its high structural stability.     

生物酶HRP催化H~2O~2氧化间苯二胺反应的研究

应用电化学分析,高效液相色谱(HPLC),紫外-可见光谱(UV-vis),红外光谱(IR)和核磁共振(NMR)等技术对辣根过氧化物酶(HRP)催化H~2O~2氧化间苯二胺(MPD)的反应进行了研究。伏安法和高效液相色谱实验说明,在所选择的酶催化反应条件下,酶催化反应生成一种产物。用化学方法制得了HRP酶催化H~2O~2氧化MPD的产物纯品。经UV-vis,IR和^1HNMR谱鉴定,产物为2,7-二氨基吩嗪。写出了酶催化反应过程,同时对酶催化反应产物的电极还原过程也进行了研究。     

Ionic Liquid‐Hemoglobin‐Carbon Paste Composite Bioelectrode and Its Electrocatalytic Activity

A new carbon ionic liquid paste bioelectrode was fabricated by mixing hemoglobin (Hb) with graphite powder, ionic liquid 1‐ethyl‐3‐methylimidazolium tetrafluoroborate (EMIMBF₄) and liquid paraffin homogeneously. Nafion film was cast on the electrode surface to improve the stability of bioelectrode. Direct electrochemistry of Hb in the bioelectrode was carefully investigated. Cyclic voltammetric results indicated that a pair of well‐defined and quasi‐reversible electrochemical responses appeared in pH 7.0 phosphate buffer solution (PBS), indicating that direct electron transfer of Hb was realized in the modified electrode. The formal potential (E^0′) was calculated as ?0.316 V (vs. SCE), which was the typical characteristic of the electrochemical reaction of heme Fe(III)/Fe(II) redox couple. Based on the cyclic voltammetric results the electrochemical parameters of the electrode reaction were calculated. This bioelectrode showed high electrocatalytic activity towards the reduction of trichloroacetic acid (TCA) with good stability and reproducibility.     

Mechanism of Chicoric Acid Electrochemical Oxidation and Identification of Oxidation Products by Liquid Chromatography and Mass Spectrometry

Electrochemical oxidation of chicoric acid (ChA) was investigated using cyclic voltammetry and chronoamperometry at a glassy carbon electrode. Chicoric acid generates single quasi‐reversible redox wave in cyclic voltammetry over a wide pH range, and an ECEC‐dimerization mechanism is proposed. Effect of glutathione (GSH) on the electrochemical oxidation of chicoric acid (ChA) was investigated in Britton−Robinson buffer solution. Ultra‐high performance liquid chromatography (UPLC) coupled with mass spectrometry (MS) was used to show that the naturally occurring chicoric acid (ChA) underwent an electrochemical oxidation in the presence of glutathione (GSH) to form mono‐, bi‐, tri‐, and four‐glutathione conjugates of chicoric acid and a mono‐glutathione conjugate of a chicoric acid dimer. The obtained results are useful for understanding and predicting the oxidative degradation pathway of chicoric acid.     

Characterization and application of an electrode modified by mechanically immobilized copper hexacyanoferrate

A newly modified electrode was prepared by mechanical immobilization of copper hexacyanoferrate (CuHCF) on a graphite electrode. The modified electrode was characterized by cyclic voltammetric experiments. The effect of different background electrolytes, pHs and scan rates on the electrochemical behaviour of the electrode has been evaluated. In NH₄Cl two reversible redox peaks were observed. The first redox peak corresponding to Cu⁺/Cu²⁺ is observed only in this medium. The second redox peak corresponds to the Fe(CN)₆ ^4–/Fe(CN)₆ ^3– couple. Both anodic peaks were used for catalytic oxidation of ascorbic acid. As the anodic current for catalytic oxidation was proportional to the amount of ascorbic acid, an analytical method was developed for the determination of ascorbic acid in commercial samples.     

Electrochemical Study of Catechol in the Presence of Dibuthylamine and Diethylamine in Aqueous Media: Part 1. Electrochemical Investigation

Electrochemical oxidation of catechol has been studied in the presence of secondary amines as nucleophiles in aqueous solution with various pH values using cyclic voltammetry and differential pulse voltammetry. Cyclic voltammetry of catechol in pure buffered solution (2.00 pH<9.00) shows one anodic and corresponding cathodic peak which relates to the transformation of catechol to corresponding o‐benzoquinone and vice versa within a quasi‐reversible two electron transfer process. Also, a little amount of o‐benzoquinone undergoes polymerization reaction. Cyclic voltammogram of catechol in the presence of nucleophilic amines, show one anodic peak in the first scan of potential but on the reverse scan the corresponding cathodic peak disappear and new peak is observed at less positive potential. In the second scan of potential also a new anodic peak is observed. On the other hand at high concentration of amines the redox peak attributable to formed polymer disappear showing that in this condition the polymerization reaction occurs at non‐measurable extent. On the basis of these observations we propose an ECE mechanism for the electrochemical oxidation of catechol in the presence of secondary amines.     

Reversible reorganization of alkyl ester groups grafted on glassy carbon electrode: Induction by a redox probe

The oxidation of the tetrabutylammonium salt of adipic acid monomethyl ester was performed to extend the concept that the oxidation of carboxylates with terminal functional groups with electrons in π-orbitals induces the covalent grafting of carbon surfaces. When 1,4-benzoquinone was used as a redox probe to identify the compaction level of the grafted film, the voltammetric behaviour of this redox probe changed by cycling. Once a reproducible and quasi-reversible wave was obtained, the repose of the electrode in the electrolyte solution during a few minutes allowed the recovery of the original voltammogram of the redox probe on the modified electrode. This behaviour is cyclic and can be understood as the result of a reversible reorganization effect of the organic film. This reorganization phenomenon is affected by the water content in the electrochemical cell, which can be explained by hydrogen bonds forming between the ester groups present in the structure film and water.     

Electrochemical Behaviour of Isoflavones Genistein and Biochanin A at a Glassy Carbon Electrode

The electrochemical behaviour of genistein and biochanin A was studied at a glassy carbon electrode by cyclic, differential pulse and square wave voltammetry. Genistein undergoes three irreversible, pH dependent oxidation reactions with the transfer of one electron and one proton from each hydroxyl group. The formation of two electroactive products that undergo reversible redox reactions was observed. Biochanin A undergoes two irreversible, pH dependent reactions due to the oxidation of the two hydroxyl groups. The electrochemical behaviour of the chemical analogue daidzein was also investigated. The electroactive centres of genistein and biochanin A were identified and their oxidation mechanisms discussed.