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     

模板法组装纳米有序阵列的研究进展

由金属、半导体、碳纳米管、聚苯胺等组成的纳米有序阵列体系,在能量存储或转换、传感等方面具有广阔的应用前景。模板法组装纳米有序阵列体系是以具有特定微孔结构的材料为模板,通过电化学沉积、溶胶-凝胶沉积和化学气相沉积等手段,让纳米单元在模板提供的受控环境中原位生成,形成纳米有序阵列体系。模板法具有可控性好、工艺简便、能耗低等优点。本文综述了模板法组装纳米有序阵列体系的研究进展,并对纳米有序阵列体系的应用前景作了展望。     

硅基底金纳米粒子微阵列电极的制备及其电化学性质的研究— 多孔硅电致发光 生物传感器研究的前期探索

用Frens法制备了不同粒径的金纳米粒子,并用透射电镜、紫外可见分光光度法进行了表征。用自组装技术得到了金膜电极表面的金纳米粒子二维阵列电极,用扫描电镜、电化学等方法对该微阵列电极进行了表征。结果表明,当金电极表面被自组装膜完全覆盖后,电化学反应不再发生,而将金纳米粒子组装到膜上以膈,才得到电化学信号。我们认为,金纳米粒子在这里对电荷的跨膜转移有很强的促进作用。对于该过程的研究,用助于理解电荷的转移机制,对进一步理解电荷隧穿过程有一定的指导意义。     

电化学沉积制备聚苯胺纳米阵列及性能研究的综合化学实验

为将导电聚合物超级电容器电极材料引入到本科教学实验中，设计了综合探究性高分子材料制备实验——电化学沉积制备聚苯胺纳米阵列及性能研究。首先采用电化学法构筑导电高分子聚苯胺纳米阵列；然后运用紫外光谱、拉曼光谱、扫描电子显微镜和电化学工作站等，分别对聚苯胺阵列的化学结构、形貌和电化学性能进行表征。从材料的合成角度来看，该实验可以使学生了解和掌握电化学合成导电聚合物的机理与方法；从材料的结构和性能表征方面来看，可以使学生学习和操作科研类的大型仪器设备，对学生的动手操作能力具有实质性的锻炼。此外，该综合性实验很好地将化学制备与材料的应用相结合，方法简单，耗时短，重复性好，可作为高分子类专业本科生综合探究性实验开设。     

碳纳米管/铜纳米结构电极材料在葡萄糖检测中的应用

利用电化学沉积法制备了碳纳米管/铜纳米结构电极材料, 采用扫描电子显微镜和电化学方法对电极表面的形貌和电化学性质进行了表征. 结果表明, 碳纳米管/铜纳米结构电极材料具有较大的电化学活性表面积、 高稳定性、 良好的导电性以及高葡萄糖电氧化活性, 有望用于葡萄糖的检测.     

功能化金纳米修饰电极自组装及其在固定化酶生物传感器中应用

功能化金纳米修饰电极是化学修饰电极,不仅具有特定功能团性能,且能提供电化学信号,可用于与待测物的电子传递,电子捕获,判定某化学反应是否发生.功能化金纳米修饰电极检测待测物,具有灵敏度高、检测限低及长久使用的优势.我们就功能化金纳米修饰电极自组装制备、电化学表征方法及其在固定化酶生物传感器方面的应用研究,进行综述报道.     

脉冲电沉积法制备Pt-TiO2 纳米管电极及其电催化性能

采用阳极氧化法在高纯钛片上原位组装TiO2纳米管阵列, 然后用脉冲电沉积方法将Pt沉积到TiO2纳米管阵列上, 制备出Pt-TiO2纳米管电极. 利用XRD和SEM对所获电极的微观结构和形貌进行表征, 结果表明, Pt纳米颗粒以花簇状分散在TiO2纳米管上, 晶粒大小约为25.6 nm. 对甲醇的电催化性能的研究结果表明, 脉冲电沉积制得的Pt-TiO2纳米管电极比TiO2纳米管电极和纯Pt片电极具有更高的电催化活性, 是Pt电极的40多倍.     

铂纳米棒有序阵列催化电极在被动式直接甲醇燃料电池中的应用

直接甲醇燃料电池(DMFC)具有能量密度高、无需充电、液体燃料添加便捷及环境友好等优点,是新一代便携式移动电源研究热点. DMFC规模应用的主要技术挑战是如何进一步提高电池性能、显著降低成本和可靠延长寿命.催化电极作为 DMFC发电核心和成本的集中体现,其电催化活性和贵金属用量直接影响 DMFC的性能和成本,开发高性能、低成本的催化电极对推进 DMFC实用化进程具有重要意义.特别是在被动式 DMFC中,阴极催化电极不仅需要提高电催化活性和大幅降低贵金属用量,而且还面临内部严重的“水淹”和氧传质受限等问题.近年来,随着纳米技术发展,有序纳米结构已逐渐应用于 DMFC催化电极的构筑中,电池性能得到显著提高.然而,目前的研究主要集中在膜电极纳米有序微孔层、纳米有序改性膜和纳米有序阳极催化电极及其阳极贵金属载量降低等方面,关于阴极催化电极在有序纳米结构以及载量降低等方面的研究相对较少.
　　本文采用模板法直接在微孔层上电沉积定向生长排列有序、直径可控的铂纳米棒阵列,并作为阴极催化电极应用于被动式 DMFC. X射线衍射和透射电镜结果表明,该铂纳米棒结构稳定,表面含有丰富的纳米晶须结构,有利于催化电极比表面积增加和电催化活性提高.不同催化电极上氧还原的极化曲线表明电极性能依下列次序变化：直径为200 nm铂纳米棒阵列电极>100 nm铂纳米棒阵列电极>商业化铂黑催化电极.电池性能表征表明,长度为1–3μm、直径分别为200和100 nm、载量为1.0 mg/cm2的铂纳米棒阵列作为阴极催化电极的 DMFC最大功率密度分别为17.3和12.0 mW/cm2.通过催化电极电化学活性面积和阻抗测试,分析其性能提高的原因可归结于有序排列的铂纳米棒阵列结构提高了电化学活性面积、增强了氧还原电催化活性并促进了阴极氧的传质.     

金微盘电极的加工和表征

微电极具有常规电极无法比拟的优良的电化学特性^[1,2].它包括单微电极和微电极阵列, 其中单微电极的整体尺寸小, 可用于微区分析研究. 目前微盘电极的工艺改善目标主要包括: 电极整体尺寸小、 电极材料和绝缘层之间的粘附性高及电极具有明确的和可重复的形状和尺寸等^[3]方面.     

铂纳米棒有序阵列催化电极在被动式直接甲醇燃料电池中的应用（英文）

直接甲醇燃料电池(DMFC)具有能量密度高、无需充电、液体燃料添加便捷及环境友好等优点,是新一代便携式移动电源研究热点.DMFC规模应用的主要技术挑战是如何进一步提高电池性能、显著降低成本和可靠延长寿命.催化电极作为DMFC发电核心和成本的集中体现,其电催化活性和贵金属用量直接影响DMFC的性能和成本,开发高性能、低成本的催化电极对推进DMFC实用化进程具有重要意义.特别是在被动式DMFC中,阴极催化电极不仅需要提高电催化活性和大幅降低贵金属用量,而且还面临内部严重的"水淹"和氧传质受限等问题.近年来,随着纳米技术发展,有序纳米结构已逐渐应用于DMFC催化电极的构筑中,电池性能得到显著提高.然而,目前的研究主要集中在膜电极纳米有序微孔层、纳米有序改性膜和纳米有序阳极催化电极及其阳极贵金属载量降低等方面,关于阴极催化电极在有序纳米结构以及载量降低等方面的研究相对较少.本文采用模板法直接在微孔层上电沉积定向生长排列有序、直径可控的铂纳米棒阵列,并作为阴极催化电极应用于被动式DMFC.X射线衍射和透射电镜结果表明,该铂纳米棒结构稳定,表面含有丰富的纳米晶须结构,有利于催化电极比表面积增加和电催化活性提高.不同催化电极上氧还原的极化曲线表明电极性能依下列次序变化:直径为200 nm铂纳米棒阵列电极100 nm铂纳米棒阵列电极商业化铂黑催化电极.电池性能表征表明,长度为1–3μm、直径分别为200和100nm、载量为1.0 mg/cm2的铂纳米棒阵列作为阴极催化电极的DMFC最大功率密度分别为17.3和12.0 m W/cm~2.通过催化电极电化学活性面积和阻抗测试,分析其性能提高的原因可归结于有序排列的铂纳米棒阵列结构提高了电化学活性面积、增强了氧还原电催化活性并促进了阴极氧的传质.     

Bioelectroanalysis with nanoelectrode ensembles and arrays

This review deals with recent advances in bioelectroanalytical applications of nanostructured electrodes, in particular nanoelectrode ensembles (NEEs) and arrays (NEAs). First, nanofabrication techniques, principles of function, and specific advantages and limits of NEEs and NEAs are critically discussed. In the second part, some recent examples of bioelectroanalytical applications are presented. These include use of nanoelectrode arrays and/or ensembles for direct electrochemical analysis of pharmacologically active organic compounds or redox proteins, and the development of functionalized nanoelectrode systems and their use as catalytic or affinity electrochemical biosensors.     

Recent advances in sensing and biosensing with arrays of nanoelectrodes

This review deals with recent advances in the field of electrochemical sensing and biosensing with nanoelectrode ensembles (NEEs) and nanoelectrode arrays (NEAs), focusing mainly on articles published since 2015. At first, a brief introduction on the properties and possible advantages which characterize electroanalytical signals at the NEE/NEA is presented, followed by an overview on the most recent theoretical advances concerning the modeling of relevant electrochemical signals. Novel nanofabrication methods and nanoelectrode materials are discussed together with original (bio)funtionalization procedures, suitable to obtain more sensitive and reliable sensors. Advanced applications of NEE/NEA-based sensors in the biological and biomedical field are presented, including their integration with living cells and application for neurochemical studies. Advances, present limits, and prospects for research in the area are finally discussed. As far as future research trends are concerned, on the one hand, there is a need for development of theoretical models which take into account specific effects that can rule electrochemistry with arrays of nanosized electrodes, such as double layer and quantum mechanical effects. On the other hand, frontier studies concerning the application of the NEE/NEA to the biomedical and neurochemical fields can open new tracks both to fundamental knowledge and application.     

Gold nanoelectrode ensembles for direct trace electroanalysis of iodide

A procedure for the standardization of ensembles of gold nanodisk electrodes (NEE) of 30 nm diameter is presented, which is based on the analytical comparison between experimental cyclic voltammograms (CV) obtained at the NEEs in diluted solutions of redox probes and CV patterns obtained by digital simulation. Possible origins of defects sometimes found in NEEs are discussed. Selected NEEs are then employed for the study of the electrochemical oxidation of iodide in acidic solutions. CV patterns display typical quasi-reversible behavior which involves associated chemical reactions between adsorbed and solution species. The main CV characteristics at the NEE compare with those observed at millimeter sized gold disk electrodes (Au-macro), apart a slight shift in E_1/2 values and slightly higher peak to peak separation at the NEE. The detection limit (DL) at NEEs is 0.3 μM, which is more than one order of magnitude lower than DL at the Au-macro (4 μM). The mechanism of the electrochemical oxidation of iodide at NEEs is discussed. Finally, NEEs are applied to the direct determination of iodide at micromolar concentration levels in real samples, namely in some ophthalmic drugs and iodized table salt.     

Responsive photonic crystals

This Review summarizes recent developments in the field of responsive photonic crystal structures, including principles for design and fabrication and many strategies for applications, for example as optical switches or chemical and biological sensors. A number of fabrication methods are now available to realize responsive photonic structures, the majority of which rely on self-assembly processes to achieve ordering. Compared with microfabrication techniques, self-assembly approaches have lower processing costs and higher production efficiency, however, major efforts are still needed to further develop such approaches. In fact, some emerging techniques such as spin coating, magnetic assembly, and flow-induced self-assembly have already shown great promise in overcoming current challenges. When designing new systems with improved performance, it is always helpful to bear in mind the lessons learnt from natural photonic structures.     

Nanoelectrode ensembles for the direct voltammetric determination of trace iodide in water

Procedures for the preparation and characterisation of ensembles of gold nanodisk electrodes (NEE) of 30 nm diameter are presented, in particular focusing on improvements in the signal/background current ratios and detection limits with respect to the electrochemical oxidation of iodide and its analytical determination in water samples. At NEEs iodide undergoes a quasi-reversible diffusion controlled oxidation with a slight shift in E _1/2 values and slightly higher peak to peak separation with respect to conventional gold disk electrodes. The double layer charging current at the NEE is significantly lower than at conventional electrodes so that the detection limit (DL) by cyclic voltammetry with NEEs in tap water is significantly lower than DL at the Au-disk millimetre-sized electrode (DL 0.3 µM at NEE vs. 4 µM for Au-disk). Finally, it is shown that NEEs in combination with square wave voltammetry can be applied for the direct determination of iodide in water samples from the lagoon of Venice, with a detection limit of 0.10 µM.     

Development and Evaluation of Gold 3D Cylindrical Nanoelectrode Ensembles

Gold 3D cylindrical nanoelectrode ensembles （NEEs）, 100 nm in diameter and 500 nm in length were prepared by electroless template synthesis in polycarbonate filter membranes, followed by selective controlled chemical etching. The morphology of the nanowires and cylindrical NEEs was imaged by scanning electron microscopy. The protruding nanoelectrodes were in good parallel order. EDX study showed that the nanoelectrode elements consisted of pure gold. The electrochemical evaluation of the 3D electrodes was conducted using the well known [Fe（CN）6]^3-/[Fe（CN）6]^4- couple. Cyclic voltammgrams （CV） show a very low double layer charging current and a higher ratio of signal to background current than 2D disc NEEs. Electrochemical impedance spectroscopy （EIS） indicates that the 3D cylindrical NEEs effectively accelerate the charge transfer process, which is in consistent with the results of CV. The linear relationship with a slope of 0.5 between lg Ipc and lg v shows that linear diffusion is dominant on the 3D cylindrical NEEs at conventional scan rates.     

One step fabrication of nanoelectrode ensembles formed via amphiphilic block copolymers self-assembly and selective voltammetric detection of uric acid in the presence of high ascorbic acid content

A novel one-step approach to glassy carbon nanoelectrode ensembles (NEEs) with the pores of 20-120 nm in radii has been developed using an amphiphilic block copolymer [polystyrene-block-poly (acrylic acid)] self-assembly. This procedure is simple and fast, and requires only conventional, inexpensive electrochemical instrumentation. Electrochemical methods were used to characterize the NEEs prepared using this new procedure. The NEEs drastically suppressed the response of ascorbic acid (AA) and resolved the overlapping voltammetric response of uric acid (UA) and AA into two well-defined peaks with a large anodic peak difference (ΔE_pa) of about 310 mV. The peak current obtained from differential pulse voltammetry (DPV) was linearly dependent on the UA concentration in the range of 0.25-50 μM at neutral pH (PBS, pH 6.86) with a correlation coefficient of 0.999, and the detection limit was 0.04 μM (S/N = 3). The NEEs has also been demonstrated to be applicable in the detection of UA in serum and urine samples with excellent sensitivity and selectivity. The NEEs will hopefully be of good application for further sensor development.     

Miniaturizing free-flow electrophoresis - a critical review

Free-flow electrophoresis (FFE) separation methods have been developed and investigated for around 50 years and have been applied not only to many types of analytes for various biomedical applications, but also for the separation of inorganic and organic substances. Its continuous sample preparation and mild separation conditions make it also interesting for online monitoring and detection applications. Since 1994 several microfluidic, miniaturized FFE devices were developed and experimentally characterized. In contrast to their large-scale counterparts microfluidic FFE (mu-FFE) devices offer new possibilities due to the very rapid separations within several seconds or below and the requirement for sample volumes in the microliter range. Eventually, these mu-FFE systems might find application in so-called lab-on-a-chip devices for real-time monitoring and separation applications. This review gives detailed information on the results so far published on mu-FFE chips, comprising its four main modes, namely free-flow zone electrophoresis (FFZE), free-flow IEF (FFIEF), free-flow ITP (FFITP), and free-flow field-step electrophoresis (FFFSE). The principles of the different FFE modes and the basic underlying theory are given and discussed with special emphasis on miniaturization. Different designs as well as fabrication methods and applied materials are discussed and evaluated. Furthermore, the separation results shown indicate that similar separation quality with respect to conventional FFE systems, as defined by the resolution and peak capacity, can be achieved with mu-FFE separations when applying much lower electrical voltages. Furthermore, innovations still occur and several approaches for hyphenated, more integrated systems have been proposed so far, some of which are discussed here. This review is intended as an introduction and early compendium for research and development within this field.     

Ultrasensitive electrocatalytic DNA detection at two- and three-dimensional nanoelectrodes

Electrochemical DNA detection systems are an attractive approach to the development of multiplexed, high-throughput DNA analysis systems for clinical and research applications. We have engineered a new class of nanoelectrode ensembles (NEEs) that constitute a useful platform for biomolecular electrochemical sensing. High-sensitivity DNA detection was achieved at oligonucleotide-functionalized NEEs using a label-free electrocatalytic assay. Attomole levels of DNA were detected using the NEEs, validating the promise of nanoarchitectures for ultrasensitive biosensing.     

Facile preparation of nanoelectrode ensembles using amphiphilic block copolymer film

Taking advantage of both the self-organizing characteristics and the amphiphilic property of poly(styrene-block-ethyleneoxide) (P(S-b-EO)), we have realized one-step fabrication of nanoelectrode ensembles (NEEs). By choosing the electrolyte solution elaborately, only the poly(ethylene oxide) (PEO) segment in the P(S-b-EO) film was swollen to serve as nanoscale tunnels for solvated ions, whereas the polystyrene segment remained robust to be the electrode mask. An electrochemical analysis indicated that a transition between linear diffusion and nonlinear diffusion could be observed due to the small diffusion coefficient of ferrocene in PEO nanodomains.