离子液体BMIMBF4-H2O中邻氯硝基苯的电化学还原性能

以离子液体BMIMBF4为溶剂和支持电解质, H2O为氢源, 采用循环伏安法、交流阻抗法研究邻氯硝基苯在Cu微盘电极上的电化学还原性能. 研究结果表明, 邻氯硝基苯在离子液体中是一个受扩散控制的反应; 由不同极化电位下的电化学阻抗谱可看出, 在高频区主要是以电化学极化控制为主, 在低频区出现直线表明电化学反应受反应物质扩散控制, 表明该电化学反应是受电化学极化和反应物扩散联合控制, 随电位负移, 电极表面电荷传质的容抗弧逐渐减小, 反应更易进行; 在电解合成实验中, 在最优条件下(E=-0.9 V, c=74.4 mmol/L, Q=517.6 C)得到的产率(86.2%)最高, 比同类反应中电化学合成文献报道值高.     

多壁纳米碳管空气电极的交流阻抗研究

研究了多壁纳米碳管、活性炭和石墨等空气电极的交流阻抗特性.结果表明,纳米碳管空气电极的阻抗谱由两个半圆组成,高频区半圆对应欧姆极化阻抗,低频区半圆对应电化学极化阻抗.催化剂Pt以纳米颗粒的形式沉积在碳管的外表面,明显减小了电极的欧姆阻抗和电化学极化阻抗,提高了氧还原反应的电催化活性.活性炭电极除存在电化学阻抗外,还存在薄液膜扩散阻抗(Nernst扩散),石墨电极形成的薄液膜反应区域较小,电极反应呈Warburg扩散阻抗特征,相应的电催化活性较低.采用交流阻抗等效电路分析方法,对拟合的动力学数据进行了解释.     

纳米结构的钯与金-钯薄膜的制备及其电催化活性

应用电位扫描法将Pd(II)离子沉积到玻碳电极表面,形成纳米结构的金属钯薄膜电极.然后在酸性溶液中控制适当的阴极电位,使该薄膜电极的钯吸收足量的活性氢,进而以吸收的氢作还原剂将Au(III)离子还原,制得Au-Pd双金属薄膜电极.扫描电镜、循环伏安法等测试表明,该电极Au-Pd沉积层对乙醇的氧化具有很高的电催化活性.     

间氯苯甲酸在Pd/Ti电极上的电化学脱氯反应

以Ti为基底电极, 在PdCl₂溶液中电沉积制备了Pd/Ti电极, 采用SEM和XPS进行表征. 采用循环伏安法研究了Cu, Ag, Ti和Pd/Ti电极对间氯苯甲酸(3-CBA)的电还原特性, 与Cu, Ag和Ti电极相比, Pd/Ti电极对3-CBA有较好的电化学还原活性. 同时采用电化学原位红外反射光谱对3-CBA在Pd/Ti电极上的电还原反应机理进行了系统分析, 结果表明3-CBA在Pd/Ti电极上的电化学脱氯反应是一个脱氯加氢过程, 3-CBA首先得到一个电子形成阴离子自由基中间体, 随后释放一个氯离子, 产生苯甲酸盐的自由基, 最后该自由基得到一个电子并夺取一个氢质子, 在电极表面脱去氯得到最终产物苯甲酸.     

Pd/PEI-GNs复合材料的制备及对对硝基苯酚的电催化还原性能

以聚乙烯亚胺(PEI)功能化的石墨烯(PEI-GNs)为载体, 利用电化学还原法制备了Pd/PEI-GNs复合物. 采用红外光谱仪、 X射线光电子能谱仪、 X射线粉末衍射仪和扫描电子显微镜等对复合物的组成、 结构和形态进行了表征. 结果表明, Pd/PEI-GNs复合物中Pd颗粒均匀分散在PEI-GNs基底上. 采用循环伏安法、 交流阻抗法和计时电流法等电化学方法研究了Pd/PEI-GNs复合物的电化学性能. 结果表明, 制备的复合物催化剂对对硝基苯酚还原具有较好的催化活性和稳定性, 这主要是由于Pd纳米颗粒在PEI-GNs载体上均匀分散以及PEI-GNs优异的电子传递能力.     

锂离子电池薄膜锡负极材料的制备及容量衰减机理研究

以电镀的方法在铜基底上沉积薄膜锡作为锂离子电池负极材料. 运用X射线衍射、扫描电镜、电化学循环伏安、电化学充放电和交流阻抗等多种方法对其结构和性能进行表征和研究. 结果表明所制备的薄膜锡电极主要为四方晶系结构, 其初始放电(嵌锂)容量为709 mAh•g^－1, 充电(脱锂)容量为561 mAh•g^－1. 电化学循环伏安研究发现在嵌/脱锂过程中薄膜锡经历了多种相变过程. 电化学阻抗谱结果说明, 首次嵌锂过程中当电极电位达到1.2 V在电极表面形成SEI膜, 而当电极电位低于0.4 V表面SEI膜出现破裂, 归因于体积膨胀所致. SEM研究表明30次充放电循环后薄膜锡负极出现龟裂现象.     

无金属可见光诱导原子转移自由基聚合法制备聚丙烯酰胺@氧化石墨烯/纳米钯复合物修饰电极及其对乙醇的检测

在金电极表面,用无金属可见光诱导原子转移自由基聚合(MVL ATRP)的方法制备聚丙烯酰胺@氧化石墨烯/纳米钯复合物修饰电极(Au/PAM@GO/Pd)。采用电化学循环伏安法(CV)、交流阻抗法(EIS)、扫描电子显微镜(SEM)、能量色散X射线光谱法(EDS)对Au/PAM@GO/Pd电极进行表征,结果表明在金电极表面成功制备了复合物。利用Au/PAM@GO/Pd电极作为电化学传感器,该传感器能成功地检测溶液中的乙醇。在最佳条件下,利用差分脉冲伏安法(DPV)该传感器检测乙醇的线性范围为1.0×10-8~1.0 mol/L,检出限(S/N=3)为1.3×10-9 mol/L,线性相关系数为0.996。     

聚脱氧腺苷酸/还原石墨烯纳米复合膜电化学传感器检测核黄素

以含32个碱基的聚脱氧腺苷酸(A32)作为黏合剂,将水合肼还原的石墨烯(RGO)固定在金(Au)电极表面,制备A32/RGO纳米复合膜电化学传感器.利用循环伏安法和交流阻抗法对传感器制备过程进行表征,并用循环伏安法和微分脉冲伏安法研究了该传感器的电化学行为.研究结果表明,与裸Au电极和A32修饰的Au电极相比,RGO/A32/Au电极对核黄素有较高的电化学活性,其还原峰电流与核黄素的浓度在0.025~2.75μmol/L范围内呈线性关系,检出限(S/N=3)为15 nmol/L.该传感器具有灵敏度高、抗干扰能力强及稳定性好等优点,可用于人尿中核黄素的分析测定.     

ATO包覆TiO2的导电性能研究

采用化学共沉淀法制备了Sb掺杂SnO_2包覆TiO_2的微纳米导电粉体。考察了不同Sb量对粉体的导电性能影响,通过XRD、SEM对粉体进行了表征。将导电粉体制成复合电极片,利用电化学工作站对其进行循环伏安和交流阻抗分析。结果表明,随着扫描速率的增加,氧化峰和还原峰分别向阴极和阳极移动,而且氧化还原峰的形状没有随着扫描速率的增加发生明显的变化;当m(SnCl_4·5H_2O)/m(SbCl_3)=10∶1时,容抗弧半径最小,且斜率最大,电阻最小,导电性最好。此结果与用电阻率测定仪测得电阻率的结果一致,说明利用交流阻抗法和循环伏安法考察导电粉体的导电性是可行的。     

Eastman-AQ/四硫富瓦烯修饰碳纤维微盘电极

利用新型的阳离子聚合物膜将四硫富瓦烯修饰到电极表面上，并研究了修饰电极的电化学行为。研究了浸泡时间、扫描速度和支持电解质对修饰电极性能的影响；循环伏安法、计时电流法和交流阻抗法表明四硫富瓦烯在膜中的扩散是控制步骤。四硫富瓦烯在膜中的第一对氧化还原峰呈现可逆的、单电子反应。用循环伏安法测得了ＴＴＦ＋ＴＴＦＺＴＴＦ反应的平衡常数。     

Electrochemical characteristics of poly(ophenylendiamine) film electrodes in phosphatic solution

The electrochemical characteristics of poly(o-phenylendiamine) (POPD) film modified electrodes have been investigated using different electrochemical techniques.The main interest is focused on the effect of potential and film thickness on the electrode process.Good agreement has been found for the apparent diffusion coefficient estimated by chronocoulometry and impedance spec-troscopy.The charge transfer process within POPD films is diffusion processes at negative and positive overpotentials and electron hopping mechanism at formal potential.The POPD film conductivity of the oxidized state is better than that of the reduced state.For all electrode processes,the H+ may penetrate the film/electrolyte interface and take part in charge transfer or protonation-deprotonation of phenazine rings.     

Inhibition effect of cerium in hybrid sol–gel films on aluminium alloy AA2024

Aluminium alloys such as AA2024 are susceptible to severe corrosion attack in aggressive solutions (e.g. chlorides). Conversion coatings, like chromate, or rare earth conversion coatings are usually applied in order to improve corrosion behaviour of aluminium alloys. Methacrylate‐based hybrid films deposited with sol–gel technique might be an alternative to conversion coatings. Barrier properties, paint adhesion and possibly self‐healing ability are important aspects for replacement of chromate‐based pre‐treatments. This work evaluates the behaviour of cerium as corrosion inhibitor in methacrylate silane‐based hybrid films containing SiO₂ nano‐particles on AA2024. Hybrid films were deposited on aluminium alloy AA2024 by means of dip‐coating technique. Two different types of coating were applied: a non‐inhibited film consisting of two layers (non‐inhibited system) and a similar film doped with cerium nitrate in an intermediate layer (inhibited system). The film thickness was 5 µm for the non‐inhibited system and 8 µm for the inhibited system. Film morphology and composition were investigated by means of GDOES (glow discharge optical emission spectroscopy). Moreover, GDOES qualitative composition profiles were recorded in order to investigate Ce content in the hybrid films as a function of immersion time in 0.05 M NaCl solution. The electrochemical behaviour of the hybrid films was studied in the same electrolyte by means of EIS technique (electrochemical impedance spectroscopy). Electrochemical measurements provide evidence that the inhibited system containing cerium displays recovery of electrochemical properties. This behaviour is not observed for the non‐inhibited coating. GDOES measurements provide evidence that the behaviour of inhibited system can be related to migration of Ce species to the substrate/coating interface. Copyright © 2010 John Wiley & Sons, Ltd.     

染料敏化太阳电池中双层结构TiO2薄膜空间的电子分布与接触界面转移过程

采用电化学阻抗谱(EIS)研究了双层结构TiO2薄膜的电子积累和与电解液接触界面的电子转移过程. 通过制备纳米颗粒单层和纳米颗粒/亚微米颗粒双层2种不同微结构的TiO2薄膜电极, 对其电容分布、 局域态密度、 薄膜内部电子传输和固/液界面电子转移过程进行了研究. 分析了纳米颗粒/亚微米颗粒双层结构电极对染料敏化太阳电池(DSC)性能的影响. 结果表明, 一定数量的电子会积累在亚微米颗粒层中引起薄膜电极化学电容的增加. 在纳米颗粒层上端覆盖亚微米颗粒后降低了界面复合电阻, 但对薄膜电极的传输性能影响较小. 因此在筛选和制备DSC散射层材料时除应具有良好的光散射性能外, 还应考虑材料的化学电容和界面转移电阻等因素.     

Platinum-modified polyaniline/polysulfone composite film electrodes and their electrocatalytic activity for methanol oxidation

The polyaniline/polysulfone (PAN/PSF) composite films were prepared by electropolymerization, and then platinum was deposited into this composite film to obtain the platinum-modified polyaniline/polysulfone(Pt/PAN/PSF) composite film electrodes. Their component, morphology and structure were characterized by FTIR spectra, scanning electron microscopy and energy dispersive X-ray spectroscopy. The results show that the composite film has a bi-layer structure with asymmetrical pores, and the platinum particles are homogeneously dispersed in the modified film electrodes. The cyclic voltammetry and electrochemical impedance spectroscopy techniques were applied to investigate the electrochemical properties and the electrocatalytic activity of the modified film electrodes, which show a promotive action for methanol oxidation and the methanol oxidation under a diffusion-controlled process.     

Electrochemical impedance studies of the undoping process of platinum phthalocyanine charge transfer microcrystals

Platinum phthalocyanine (PtPc) microcrystal films undergo three successive electrochemical oxidations. Each of these processes is associated with anion insertion or doping. The reverse process of anion insertion, undoping, has been investigated using electrochemical impedance spectroscopy and in-situ UV–vis spectroscopy. The impedance theory of conductive polymer films developed by Vorotyntsev et al. is applicable to this process. The kinetics of the undoping process depend upon the previous oxidative treatment, and thus the doping level. Three different states of the film can be demarcated, depending on the degree of oxidation (and thus the degree of doping) of the PtPc film. These are called the lightly doped, the conductive and the over-doped state, respectively. For lightly doped films, the film conductivity, the redox capacitance, the diffusion coefficient for charge transport and the rate of electrochemical reaction all decrease with decreasing potential. The film conductivity depends upon the concentration of free charge carriers. For the more highly doped conductive film, all of the above parameters are greatly enhanced, and the electrochemical reaction is accelerated and proceeds at a very high rate. The potential dependence of the redox capacitance and the diffusion coefficient depends on the type of anion. During undoping at 0 V, unusually high diffusion coefficients with a magnitude of order 10⁻² cm² s⁻¹ are observed and are attributed to the strong interactions between the electronic and ionic carriers during the phase transformation. For the over-doped film, undoping leads to an increase in the film conductivity and electrochemical reaction rate. The potential dependence of the redox capacitance and diffusion coefficients for charge transport implies strong interactions within the film. Hypsochromic shifts in UV–vis spectra with decreasing potential indicate conformational relaxation during the undoping process. SEM investigation confirms that the doped film swells during the de-doping process.     

溶胶-凝胶法制备薄膜型TiO2光催化剂

用TiCl4作原料,通过溶胶-凝胶法在单晶硅基片上制备了TiO2纳米薄膜,并用XRD,AES,XPS以及紫外反射光谱等手段,对TiO2薄膜的结构进行了研究.结果发现,TiO2薄膜以锐钛矿型晶相存在.TiO2薄膜层与硅衬底间无明显的界面扩散反应.掺杂的Pd在还原前的薄膜中以氧化态存在,还原后则以高分散的金属态存在.掺杂的Pt在还原前后均以金属态存在,但还原后产生颗粒聚集.掺杂Pd的TiO2薄膜经还原后,其紫外吸收强度明显提高,主吸收峰发生红移.     

氧化铑电致变色薄膜的制备、结构及性能

采用溶胶_凝胶方法在ITO导电基底上制备氧化铑电致变色薄膜 .当在碱性溶液中对薄膜分别施加阴极和阳极电位时 ,薄膜即呈现由亮黄到深绿的可逆变化 .采用原位XRD、TG_DTA、IR、XPS等方法对薄膜的结晶态、热处理过程以及膜的化学组成进行分析 .应用交流阻抗法计算了薄膜变色过程的扩散系数 ,结果表明该膜基本可以用于变色器件     

氢在非晶态合金MmNi4.5Mn0.5中的扩散

合金MmNi_4.5Mn_0.5(Mm代表混合稀土元素)被认为是目前最有实际应用前景的贮氢材料,其晶态贮氢过程的研究,已有过报道^[1]。本文用电化学方法研究氢在非晶态MmNi_4.5Mn_0.5的扩散行为。     

稀土盐对铝合金阳极化过程的影响

在阳极化溶液中添加稀土盐得到的铝合金氧化膜在腐蚀试验中表现出优良的耐蚀性能,现场椭圆法对阳极氧化过程的研究结果表明,稀土盐的加入,对椭圆编振参数的振荡方式没有显著影响,但却使振荡的周期和振幅发生了一些变化,由此可以推知,稀土盐的加入并未改变氧化膜的组成,但却在一定程度上影响了成膜过程,使膜的结构发生了变化。对椭圆数据进行定量分析的结果进一步表明：加入稀土盐后,氧化膜多孔层生长速率加快,阻挡层厚度增加,多孔部分变得更加致密,这种结构上的变化是阳极化膜耐蚀性能得以提高的主要原因,EDAX和TEM分析结果也证实了椭圆法研究的结果。