生物氧化还原研究中的薄层电化学技术

标准氧化还原电位 E~(0′)和电子转移化学计量数 n 的测定是生物氧化还原体系研究中的一个重要方面.由于许多生物分子会在电极上吸附,有些蛋白分子的氧化还原中心位于蛋白结构的内部,它们同电极的异相电子转移过程很不可逆或非常缓慢,因而难于用常规的电化学方法进行 E_(0′)和 n 值的测量。近年来薄层电化学技术的发展为这方面的研究打开了方便之门,本文简要介绍其原理及应用。     

氮氧自由基研究 XVIII: 水溶液中哌啶氮氧自由基单电子氧化电极反应动力学参数的测定

氮氧自由基可作为电子给体或受体,与氧化剂或还原剂发生单电子转移反应,也能在电极上被氧化或还原。深入研究氮氧自由基的电化学行为,对于阐明氮氧自由基的电子转移反应机理有着重要的意义,以往,仅Suemmermann报道过哌啶氮氧自由基在乙腈溶液中单电子氧化电极反应的动力学参数。我们曾研究了哌啶氮氧自由基于水溶液中的电化学行     

CoTPP电化学催化还原溴代环己烷的机理

以电化学循环伏安、现场ESR电化学以及现场薄层电化学方法研究了电生Co(Ⅰ)TPP与溴代环己烷的反应机制.在DMF中,Co(Ⅱ)/Co(Ⅰ)的氧化还原有明显的催化溴代环己烷还原的特征,反应现场有自由基生成.反应产物之一是Co-C键化合物,可以在-1.30V(SCE)一电子还原.当存在CH₂=CHCN时,生成另一种Co-C键化合物,该化合物在-1.10V(SCE)处一电子还原.证明溴代环己烷与Co(Ⅰ)TPP反应主要是经过形成烷基自由基的机制进行的.     

聚苯胺对2,5-二巯基-1,3,4-噻二唑氧化还原反应的电化学催化作用的循环伏安研究

研究了聚苯胺(PAn)膜电极在2,5-二巯基-1,3,4-噻二唑(DMcT)溶液中电化学处理或浸泡后的循环伏安(CV)曲线的变化规律.实验结果表明,PAn膜电极在DMcT溶液中进行电化学处理或浸泡过程可使DMcT进入PAn膜内部与PAn形成复合物.PAn对DMcT的电化学催化作用可能和二者之间形成的电子给体-受体复合物有关.该复合物的电化学氧化还原特性不同于PAn和DMcT,其氧化还原反应速率和可逆性均优于DMcT.     

蒽醌/聚吡咯复合膜修饰电极的电化学行为和电催化活性

在水溶液中制备了掺杂蒽醌磺酸盐(AQS)的聚吡咯(PPy)/玻碳复合膜修饰电极,采用循环伏安法和旋转圆盘电极技术研究了该修饰电极在不同pH值溶液中的电化学行为以及在pH=5.5的磷酸盐缓冲溶液中对氧还原反应的电催化性能和动力学.结果表明,与裸玻碳电极相比,PPy膜的存在不仅降低了AQS的反应电位和峰电位差,而且增大了其氧化还原反应的峰电流,H2AQ/HAQ-氧化还原对的电离常数为9.5.AQS/PPy膜修饰电极上氧的还原主要是两电子还原为H2O2的不可逆过程,H2AQ对氧还原反应起主要催化作用,还原过程符合异相氧化还原催化机理.该修饰电极具有良好的电化学重现性.     

含多个氧化还原中心的卟啉化合物的电化学及光谱电化学行为(Ⅰ)

在DMF及DMSO中用循环伏安法、现场紫外可见光谱电化学方法及现场FT-IR光谱电化学方法研究了含多个氧化还原中心的卟啉化合物[四(对-硝基苯基)卟啉合钴(Ⅱ)]的氧化还原性质。指出该化合物的第一步氧化或第一步还原为中心金属钴失去或得到1个电子;第二步还原为卟啉环meso位的4个对硝基苯基上的硝基在同一电位下各得1个电子,形成相应的阴离子自由基;第三步还原为卟啉环得到1个电子,但该步反应不可逆。同时发现硝基与卟啉环及中心金属钴之间存在分子内电子相互作用,而4个硝基取代基之间未发现分子内电子相互作用。     

含多个氧化还原中心的卟啉化合物的电化学及光谱电化学行为(Ⅰ)

在DMF及DMSO中用循环伏安法、现场紫外可见光谱电化学方法及现场FT-IR光谱电化学方法研究了含多个氧化还原中心的卟啉化合物[四(对-硝基苯基)卟啉合钴(Ⅱ)]的氧化还原性质。指出该化合物的第一步氧化或第一步还原为中心金属钴失去或得到1个电子；第二步还原为卟啉环meso位的4个对硝基苯基上的硝基在同一电位下各得1个电子,形成相应的阴离子自由基；第三步还原为卟啉环得到1个电子,但该步反应不可逆。同时发现硝基与卟啉环及中心金属钴之间存在分子内电子相互作用,而4个硝基取代基之间未发现分子内电子相互作用。     

双水杨醛缩乙二胺烷基钴(Ⅲ)配合物的电化学行为及光谱电化学表征

用循环伏安法研究了双水杨醛缩乙二胺烷基钴(Ⅲ)配合物[RCo(Salen),R=CH₃,C₂H₅,n-C₄H₉,i-C₄H₉]在热解石墨电极上的电化学行为。RCo(Salen)的电化学氧化或还原均为可逆的单电子过程;氧化时钴的价态变化为Co^Ⅲ→Co^Ⅳ,还原时为Co^Ⅲ→Co^Ⅱ→Co^Ⅰ,并伴有Co─C键的断裂和R·自由基的产生。氧化产物和还原产物均不稳定,R影响电化学性质,随着R给电子能力的增强,氧化反应的电位和还原反应的电位均负移。光谱电化学实验的结果提供了进一步的验证。     

二茂铁基超支化聚氨酯的电化学性能

通过循环伏安法(CV)测定了二茂铁基超支化聚氨酯(HAPE-Fc)的电化学性能.结果表明:HPAE-Fc表现为单对氧化还原峰,在二茂铁接枝到超支化聚氨酯上以后,二茂铁基团依然保持着自身的氧化还原独立性,具有较强的电子转移速率,这是其具有电化学特性和催化作用的前提条件.通过分析扫描速率与HPAE-Fc电化学行为之间的关系,发现HPAE-Fc的电极过程既受扩散控制,同时也受电极反应的控制.     

杨梅酮的电化学和光谱性质研究

应用循环伏安和紫外光谱法研究杨梅酮氧化还原性质及其稳定性.结果表明:在B-R缓冲溶液中玻碳电极上,杨梅酮的氧化还原表现为两步氧化反应和两步还原反应.氧化反应对应于B环4-′OH和C环3-OH的氧化,还原反应对应于C环4位羰基还原为中间体自由基之后再进一步还原生成羟基.以上各步反应均为单电子单质子电极过程.杨梅酮的氧化还原反应与溶液pH关系密切,但其原因来自于去质子化作用,并导致它的抗氧化能力增强,但其最终氧化产物没有电化学活性,并吸附在电极表面,阻碍了电极过程电子传递.在pH 7.45~12.00范围内,杨梅酮也因去质子化作用导致紫外光谱Ⅰ带和Ⅱ带随pH增加,而发生红移,分解作用加剧.同时分解作用还与放置时间有关.     

荧光分析中的氧化还原反应

本文主要综述了作者多的来研究的氧化还原反应体系及其在荧光分析中的应用，并作用评述。     

Simple voltammetric approach for characterization of two-step surface electrode mechanism in protein-film voltammetry

Many enzymes embedding multivalent metal ions or quinone moieties as redox-active centres undergo electrochemical transformation via two successive electron transfer steps. If electrochemical features of such redox enzymes are analyzed with “protein-film voltammetry”, one frequently meets a challenging reaction scenario where the two electron transfers take place at the same formal potential. Under such conditions, one observes voltammogram with a single oxidation-reduction pattern hiding voltammetric features of both redox reactions. By exploring some aspects of the two-step surface EECrev mechanism one can develop simple methodology under conditions of square-wave voltammetry to enable recognizing and characterizing each electron transfer step. The method relies on the voltammetric features of the second electron transfer, which is coupled to a follow-up chemical reaction. The response of the second electron transfer step shifts to more positive potentials by increasing the rate of the chemical reaction. The proposed methodology can be experimentally applied by modifying the concentration of an electrochemically inactive substrate, which affects the rate of the follow-up chemical reaction. The final voltammetric output is represented by two well-separated square-wave voltammetric peaks that can be further exploited for complete thermodynamic and kinetic analysis of the EECrev mechanism.

     

Controlling an Electron‐Transfer Reaction at a Metal Surface by Manipulating Reactant Motion and Orientation

The loss or gain of vibrational energy in collisions of an NO molecule with the surface of a gold single crystal proceeds by electron transfer. With the advent of new optical pumping and orientation methods, we can now control all molecular degrees of freedom important to this electron‐transfer‐mediated process, providing the most detailed look yet into the inner workings of an electron‐transfer reaction and showing how to control its outcome. We find the probability of electron transfer increases with increasing translational and vibrational energy as well as with proper orientation of the reactant. However, as the vibrational energy increases, translational excitation becomes unimportant and proper orientation becomes less critical. One can understand the interplay of all three control parameters from simple model potentials.     

Charge permutation reactions in tandem mass spectrometry

Central to the tandem mass spectrometry experiment is the process that gives rise to product ions, i.e. the reaction intermediate to stages of mass analysis. Changes in mass or charge of the parent ion (or both) are generally readily detected by all forms of tandem mass spectrometry. Charge changing, or charge permutation, reactions have a long history in mass spectrometry. However, with the advent of new ionization methods, such as electrospray ionization, and the expansion of tandem mass spectrometry instrumentation to include ion trapping instruments, the past decade has seen a major increase in the types of charge permutation reactions that can be studied. Most charge permutation reactions involve electrons or protons as the charge mediating agents. This report, therefore, provides an overview of charge permutation reactions involving protons or electrons. Particular emphasis is placed on processes that involve interactions of precursor ions with gaseous neutral species, electrons or oppositely charged ions. Charge permutation reactions involving electron gain/loss are described first according to a rough order of the energy required for the reaction beginning with the most endoergic reactions and ending with the most exoergic reactions. An analogous approach is then taken with charge permutation reactions involving proton gain/loss. Important charge permutation reactions discussed herein, among others, include those referred to as charge inversion, charge stripping, electron capture dissociation, collision-induced ionization and charge separation. These reaction types, and others described herein, are the subjects of active research and are also finding use in many current areas of application. Copyright © 2004 John Wiley & Sons, Ltd.     

Electron production and loss processes in a spectrochemical inductively coupled argon plasma

The behavior of inductively coupled plasmas for spectroscopic purposes has been studied extensively in the past. However, many questions about production and loss of electrons, which have a major effect on this behavior, are unanswered. Power interruption is a powerful diagnostic method to study such processes. This paper presents time resolved Thomson scattering measurements of the electron density n_e and temperature T_e in an inductively coupled argon plasma during and after power interruption. In the center of the plasma the measured temporal development of n_e and T_e can be attributed to ambipolar diffusion, three-particle recombination and ionization. However, at the edge of the plasma an additional electron loss process must be involved. In addition, the high electron temperature during power interruption indicates the presence of an electron heating mechanism. The energy gain by recombination processes is shown to be insufficient to explain this electron heating. These discrepancies may be explained by the formation and destruction of molecular argon ions, which can be present in significant quantities.     

Carbonylation reactions

Conclusions From the UV spectra it follows that the chain reaction for the carbonylation of piperidine, initiated by CuCl₂, proceeds via the Intermediate formation of charge-transfer complexes, in which the Cu²⁺ ion undergoes oxidation-reduction reaction with the free electron pair of the amine.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 12, pp. 2705–2708, December, 1973.     

Photo-induced dimerization of 1-naphthoxide anion: Electron transfer mechanism

Irradiation of sodium 1-naphthoxide in MeOH gave selectively 1,4-dihydro-4',8-dihydroxy-1,1'-binaphthyl 2. A similar reaction in PhH afforded the regioisomer 5, along with 6, Structural proof is presented for these hitherto unknown dimers. The reaction is completely quenched in the presence of naphthalene, a good electron scavenger. This new type of photodimerization was proved to be initiated by intermolecular electron-transfer from the excited 1-naphthoxide anion to the ground state one to give the oxidation-reduction dimers.     

丙烯酰胺与N,N′-亚甲基双丙烯酰胺的共聚反应研究

本文利用凝胶模量测定法、气相色谱法和紫外光谱法对丙烯酰胺与N,N’-亚甲基双丙烯酰胺水溶液共聚反应进行了研究,证实了N,N’-亚甲基双丙烯酰胺的反应活性明显大于丙烯酰胺的反应活性。用气相色谱法测得单体的竞聚率分别为r_(AM)=0.117,,r_(Bis)=5.756;用紫外光谱法研究了聚合反应中氧化还原引发剂浓度和反应温度对聚合反应速率的影响,得出共聚反应速率方程中,氧化剂的方次为0.66,还原剂浓度的方次为0.55,并求出共聚反应表现活化能为37.1KJ/mol。     

构建光催化氧化-还原体系的研究进展

光催化氧化-还原体系能够同时驱动光催化氧化反应和还原反应,产生协同效应,从而提高光催化反应的活性。在此,提出了构建光催化氧化-还原体系的原则,并介绍了光催化还原硝基芳烃耦合氧化有机物、光催化还原重金属离子协同氧化有机物、光解水制氢协同氧化有机物三个方面的实例。接着,阐述了光催化氧化-还原体系的反应机理,期望通过构建光催化氧化-还原体系,更有利于太阳能转化并缓解环境和能源问题。     

Mo-Fe-S三元包合物氧化还原特性的研究

本文结合电化学测量和量子化学计算对Mo-Fe-S三元包合物的氧化还原特性进行了研究。用铂电极测得的该包合物在0.1MKClO₄-DMF溶液中的循环伏安图显现出两对氧化-还原峰,由此得到的电化学参数与EHMO计算结果都表明,电位较正的一对峰相应于Fe(Ⅲ)/Fe(Ⅱ)的氧化还原,反应不可逆。电位较负的一对峰相应于Mo(Ⅴ)/Mo(Ⅳ)的氧化还原反应半可逆。