纳米阵列电极研究

纳米阵列电极作为一种人工组装的纳米结构体系,具有高传质速率、低双电层充电电流、小时间常数、小IR降及高信噪比、可操作性强和测量灵敏度高等优势,因而在电化学理论研究、生物传感器、电催化材料和高能化学电源电极材料等方面等具有广阔的应用前景。迄今为止,人们采用多种材料设计制备出包括圆盘状、圆柱形、球形、圆锥形、叉指状和井状等各种形状的纳米阵列电极。其制作方法主要包括模板法、刻蚀法和自组装法等,电极的表征主要采用电子显微镜技术和电化学方法。本文结合我们的工作和国内外文献,就纳米阵列电极制作方法、表征和应用等方面进行了评述,并对目前纳米阵列电极研究中存在的问题及发展前景进行了探讨和展望。     

纳米阵列铂电极的样模法制备与应用

双多孔氧化铝为样模,利用直流沉积法自组装纳米阵列Ｐｔ电极。该电极在Ｆｅ（ＣＮ）＾４－６溶液中的线性扫描伏安图呈现Ｓ型稳态曲线,对甲醇的氧化具有很高的电催化活性。另外,以该电极作为表现增强拉曼散射的活性基底,现场研究甲醇的电化学氧化过程,检测出中间产物单端吸附的ＣＯ。     

溅射金膜修饰玻片电极检测六价铬

采用离子溅射技术制备了一种新型金膜修饰片状玻璃电极。线性扫描伏安分析表明六价铬在该电极上具有良好的电化学响应。通过优化溅射时间、溅射电流、电解质等参数,得到线性扫描伏安法的检出限(S/N=3)为6.5μg/L,安培法的检出限为2.0μg/L。电极批间重现性为9.2%(n=10),同批次电极间的重现性为9.2%~25.8%(n=10)。该电极制备过程简单,成本低,可实现批量制备。应用该电极对塑料及湖水中的六价铬含量进行检测,结果与HPLC-ICP-MS测定值基本一致。     

微电极研究 ⅩⅤ.微带电极及阵列微带电极上的扩散

本文讨论了微带电极的计时电流、扩散层与时间的关系;研究了微带阵列电极的扩散层交叠情况及其对计时电流的影响;进而对微带阵列电极上电极间的屏蔽效应进行了研究,屏蔽效应与电解时间、电极间距离及电极宽度有关,用已有的实验结果验证了本文的理论分析.     

纳米阵列电极研究进展

从纳米阵列电极的制作、基本原理和应用 3方面综述了纳米阵列电极的研究进展。着重阐述了模板法和自组装法制作纳米阵列电极的具体过程以及纳米阵列电极的扩散电流理论 ,对纳米阵列电极在生物传感器、电化学动力学、电化学分析等方面的应用作了介绍     

白血病细胞酶联免疫酶催化银沉积于插指电极阵列电化学免疫分析新方法

建立了一种检测白血病细胞表面抗原的细胞酶联免疫电化学分析新方法. 该方法兼有细胞酶联免疫分析抗原、抗体结合的特异性和插指电极阵列酶催化银沉积电化学分析的灵敏性. 在聚苯乙烯微孔板中包被白血病细胞, 先后加入鼠抗人抗体及碱性磷酸酶(ALP)标记的马抗鼠抗体, ALP催化抗坏血酸磷酸酯(AAP)水解成抗坏血酸(AA), AA使银离子还原成银单质并沉积到插指电极阵列表面, 导致插指电极阵列上相邻两个梳齿导通. 通过对电导率的测定, 可实现对细胞表面抗原的高灵敏分析. 此分析方法灵敏度高(可检测出50个左右的HL-60细胞)、特异性好, 且可用于大量样品的分析, 为白血病等肿瘤疾病的早期诊断和免疫分型提供了新技术. 此外, 该方法也可用于细胞表面分子基因工程抗体活性的检测.     

金电极基本性质的研究综述

该文从金电极的电化学行为影响因素、阴离子表面吸附和电极面积求算3个方面对金电极的基本性质进行了综述.金电极基本性质的探讨对于相关领域的研究具有重要的指导意义.     

铅纳米线阵列的制备

使用电化学沉积方法,在有序的氧化铝模板(AAO)孔洞中制备了铅纳米线有序阵列。用X射线衍射仪(XRD)、场发射扫描电子显微镜(FE-SEM)、透射电子显微镜(TEM)对样品的结构、形貌、进行表征和观测。XRD的结果表明所制备的样品为纯的立方面心铅,且纳米线生长沿<220>有很好的取向。FE-SEM的图片清晰地说明铅纳米线阵列是大面积、高填充率和高度有序的。TEM的结果显示纳米线直径均匀、表面光滑且长径比大。     

快捷两步法制备金纳米电极用于活体多巴胺检测

用微电极进行活体检测神经化学物质属于侵入式分析,会对脑组织产生不可避免的损伤,进而在生理上产生一些信号干扰检测过程. 减小电极的尺寸对于减小对脑组织的损伤非常重要. 该研究报道了一种新型制备金纳米电极的方法并将其用于活体鼠脑内多巴胺分析研究. 这种金纳米电极的制备过程包含两步：1）通过离子溅射在毛细管的尖端覆盖一层金种子;2）把覆盖有金种子的毛细管浸入氯金酸和盐酸羟胺混合溶液中湿法沉积生成连续导电金膜. 制备好的纳米电极尖端约300 ~ 400 nm. 该金纳米电极可以应用于多巴胺的检测,并且在多巴胺浓度1.0 ~ 56.0 μmol·L^-1范围内有很好的线性响应,最低检测限低至0.14 μmol·L^-1（信噪比=3）. 该金纳米电极具有优异的电化学性能,可以成功的应用于检测鼠脑纹状体儿茶酚胺的释放.     

基于阵列电极的新型混合电容器

混合电容器由于兼具电池高能量密度和超级电容器高功率密度的优势,成为当前储能领域的研究热点。然而,电池电极和电容电极之间容量和功率的不平衡严重限制了混合电容器的实际性能。因此,如何实现二者的有效匹配,优化器件性能是混合电容器实用化的关键。阵列电极的使用打破传统粉末电极中不导电粘结剂对电化学动力学的限制,其独特的结构为正负极的匹配提供了新策略。此专论结合新型储能器件的研究现状以及本课题组在混合电容器方面的探索,简单探讨了混合电容器的储能机理和阵列结构作为电极材料的优势,着重介绍了本课题组近年来在混合电容器领域的研究工作,针对存在的科学问题提出了相应的解决方案,阐明了阵列电极混合电容器在柔性/可穿戴电子器件等领域的应用前景,并展望了混合电容器在未来的发展方向和挑战。     

电化学制备有序聚苯胺纳米线阵列

以有序碳纳米管阵列电极为基底电极,在硫酸或高氯酸溶液中,分别探明不同电化学聚合方法以及苯胺单体浓度对聚苯胺形貌的影响. 结果表明：采用循环伏安法无法制备出聚苯胺纳米线;而应用恒电位法虽可制得聚苯胺纳米线,但纳米线不能形成有序阵列;只有应用恒电流方法,并且以高浓度苯胺的高氯酸溶液作为聚合溶液,方能制得有序聚苯胺纳米线阵列.     

氯霉素分子印迹聚合膜电极的制备及氯霉素检测

以邻氨基酚(OAP)为功能单体,氯霉素(CAP)为模板分子,用电化学聚合的方法在Pt上合成了CAP分子印迹（MIP）OAP膜(CAP-MIP-OAP/Pt)电极,通过扫描电子显微镜和电化学技术对聚合膜的结构和性能进行了表征。 结果表明,该膜电极对CAP检测有较好的选择性和灵敏度,CAP检测的线性范围为4.33×10-8～3.09×10-6 mol/L,检出限为2.5×10-8 mol/L。     

氯霉素分子印迹复合膜的制备及电化学

采用电化学聚合法合成了对氯霉素（CAP）有快速响应和高灵敏度的聚苯胺/聚吡咯分子印迹复合膜修饰电极。 通过微分脉冲伏安法、扫描电子显微镜对制备的分子印迹复合膜的电化学性质及表面形貌进行了表征。 结果表明,以铁氰化钾为电化学探针,该膜对CAP的测定电化学信号响应快速、灵敏度高、选择性和膜再生性能良好。 对CAP检测的线性范围为5.00×10-8～1.05×10-6 mol/L,检测限为2.09×10-9 mol/L。     

Preparation of Nanogapped Gold Nanoparticle Array for DNA Detection

A novel DNA detection technique using a gold nanoparticle array film electrode has been reported here. The gold nanoparticles molecularly linked with binder molecule (1,10‐decanedithiol) were separated 1.3 nm from each other, and the DNA conductivity change from single to double strand was measured by monitoring a voltage drop across the particles, between which a probe of a 12‐mer oligonucleotide was immobilized. In adding a complementary oligonucleotide on the nanoparticle film chip, an immediate decrease in the film resistance (ca. 1.4 Ω) due to a hybridization event occurred in a reproducible manner with this simple setup. In the paper, we have an interest in the primary sensing properties; effect of the film resistance on the sensor response, dependence of the resistance change on the DNA concentration, and the performance of the system for DNA detection including single nucleotide polymorphisms were described.     

对插型阵列微带电极的制作及其电化学特性研究

用微电子光刻方法制作了对插型阵微带电极（ＩＤＡ），并通过ＳＥＭ对ＩＤＡ电极进行了表征，将微Ａｇ／ＡｇＣｌ参比电极和微铂丝对电极固定在ＩＤＡ电极附近，构成了微电解池，考察了该电极的循环伏安及计时电流特性，并用微带电极的扩散理论和Ｃｏｔｔｒｅｌｌ 公式对ＩＤＡ电极的准稳太电流进行了处理，指出了它们之间产生偏差的原因，研究了ＩＤＡ电极的“发生－收集”效应，测定了该电极的屏蔽因子、反馈因子和收集效率。     

A Simple Method for Fabrication of Gold Nanoelectrodes

A facile method has been developed for the fabrication of Au nanoelecrodes (Au NEs).The tip of Au NEs can be controlled within the range from dozens to hundreds of nanometer.     

Non‐Enzymatic Electrochemical Detection of Glucose with a Gold Nanowire Array Electrode

High‐performance electrodes for in vivo electrochemical detection of glucose (GO) are highly desirable. In this work, we propose a new approach to efficiently and precisely prepare a Au nanowire array electrode (ANAE) with a line width of 78 nm and a large sensor area of 60 mm×60 mm for GO detection. In this approach three techniques, i.e., vacuum sputtering‐deposition, holography photolithography, and argon ion‐beam etching, are integrated. The fabricated ANAE exhibits good performance for GO detection. A linear amperometric response to the oxidation of GO in a concentration range of 0.4–10 mM is observed. The ANAE is characterized by its high detection sensitivity, selectivity, stability and good biocompatibility. All of these make it a promising tool for GO detection and other relevant applications.     

Microsensor Chip Integrated with Gold Nanoparticles‐Modified Ultramicroelectrode Array for Improved Electroanalytical Measurement of Copper Ions

This paper presents a microsensor chip integrated with a gold nanoparticles‐modified ultramicroelectrode array (UMEA) as the working electrode for the detection of copper ions in water. The microsensor chip was fabricated with Micro‐Electromechanical System technique. Gold nanoparticles were electrodeposited onto the surface of UMEA at a constant potential of ?0.3 V. The ratio d/R_b of interelectrode spacing (d) over the individual electrode’s radius (R_b) was investigated to improve the electrochemical performance. The UMEA with a d/R_b of 20 showed the best hemispherical diffusion mode, resulted in fast response time and high current response. The gold nanoparticles increased the active surface area of UMEA by not changing the geometries of UMEA, and the current response was increased further. Incorporating the optimized characteristic of UMEA and gold nanoparticles, the microsensor showed a good linear range from 0.5 to 200 µg L^?1 of copper ions in the acetate buffer solutions with the method of square wave stripping voltammetry. Compared with the gold nanoparticles‐modified disk electrode, the gold nanoparticles‐modified UMEA showed higher sensitivity (0.024 µA mm^?2 µg^?1 L) and lower limit of detection (0.2 µg L^?1). Water samples from river water and tap water were analyzed by the microsensor chip with recovery ranging from 100.7 % to 107.8 %.     

氯丙嗪分子印迹敏感膜传感器的制备与应用

以氯丙嗪为模板分子,邻氨基酚为功能单体,在金电极表面电聚合制备具有特异性识别孔穴的氯丙嗪分子印迹敏感膜(MIP)。 采用循环伏安法(CV)、差分脉冲伏安法(DPV)等研究了印迹膜的性能、结构和分子印迹效应,并与其结构相似的化合物奋乃静和异丙嗪的选择性响应进行了比较,发现传感器对氯丙嗪具有良好的选择性。 氯丙嗪浓度在6.0×10-7～9.0×10-5 mol/L范围内与峰电流呈线性关系,线性方程为:I(μA)=61.25lg c(μmol/L)+23.47(r=0.9975),根据DL=3δb/s计算检出限为2.0×10-7 mol/L,该传感器具有良好的重复性、再生性和高灵敏度。     

Integrated pulsed amperometry for the analysis of organic compounds

Integrated pulsed amperometric detection (IPAD) was applied for the detection of organic compounds for flow injection analysis. The pulse waveform used in the integrated pulsed amperometry consisted of three steps: detection potential, oxidation potential, and adsorption potential. The pulse waveform was applied to the working electrode as the analyte flowed through the electrochemical cell. Unlike ordinary pulsed amperometry, a faradaic current was integrated over the duration period of the detection potential in the IPAD. Therefore, the total charge was measured by integrating the current after the detection potential was applied. The current for the initial 10 ms, after applying the detection potential, was excluded from the integration due to a large charging current at the initial period. Compared with pulsed amperometry, integrated pulsed amperometry provides a better signal-to-noise ratio and a lower detection limit. This method was applied to the quantitative analysis of thiourea as a representative analyte of organosulfur compounds in a flow injection analysis.