有序纳米线/棒/管阵列材料的研究进展

概述了有序纳米线/棒/管阵列的性质、应用及制备方法的研究进展,着重介绍了有序纳米线/棒/管阵列材料的制备方法如气相-液相-固相生长法、气相-固相生长法、模板法和溶剂热法,以及阵列材料在磁、场发射、激光、电化学、光电化学和催化方面所具有的独特性质与应用,展望了该领域的研究前景。     

金、铜金属纳米棒或纳米线的AFM和SERS的研究(英文)

通过电化学氧化法制备具有不同孔径氧化铝模板 ,利用交流电镀的方法在模板中沉积金属 ,再用酸溶解模板可以得到相应尺度的金属纳米线或纳米棒的阵列 .本文利用原子力显微镜和表面增强拉曼技术分别表征了金和铜两种金属纳米线阵列 .研究结果表明 ,作为探针分子的硫氰(SCN )在金属纳米线上的碳氮三键的振动频率随纳米线直径的增大而蓝移 .这一现象可能是因为尺寸效应对纳米线的费米能级造成影响 ,使不同直径的金属纳米线电子结构存在微小的差别 .     

Cu/PAA复合膜的偏振特性

应用扩孔和增大阳极氧化电压的方法制备了不同孔径的多孔铝模板,并以交流电沉积法在该模板沉积铜纳米线.测量了铜/多孔铝复合膜的透射光谱和偏振光谱.实验表明,扩孔和增加阳极氧化电压都使样品的透射率下降,但扩孔不能提高它的偏振性能;提高模板氧化电压则可以提高样品的消光比,且消光比随纳米线直径的增加而增加.     

银纳米线表面等离子波导研究进展

近年来,基于银纳米线表面等离子极化子的研究得到了迅猛的发展。银纳米线支持的表面电磁波可以沿金属-电介质的界面进行传导,并且能够实现二维亚波长模式受限,这种奇异特性使得银纳米线在设计集成光子信号传输系统领域具有独特的应用前景.本文中作者评述了银纳米线的制备、纳米线表面等离子成像以及纳米线光学元件和器件方面取得的最新研究进展,分析了表面等离子波导所面临的一些重要问题及其应对策略.     

碳催化剂在催化反应中的应用

由于碳材料表面存在缺陷,可生成具有不同性能的活性位,因此可催化不同的热催化反应.我们首先介绍了单质碳材料的表面结构化学:其表面活性位主要为含杂原子官能团;然后对其可催化的反应进行了介绍:碳单质材料可催化选择性氧化反应、高级氧化反应、还原反应、烷烃活化反应、酸催化反应、电催化还原和氧化反应等.对碳单质催化剂的制备方法、所...     

离子液体中电沉积半导体材料的研究

离子液体具有稳定性高、溶解性好和电化学宽窗口等优点,是理想的电解液。在离子液体中,可以得到在水溶液或其他有机电解液无法沉积的半导体材料,并且离子液体电沉积方法简便灵活,可以控制半导体材料的形貌和尺寸,在制备纳米半导体的领域中具有非常重要的现实意义。本文介绍了离子液体的性能特点,并综述了几种离子液体中电沉积半导体材料。其中包括单质半导体薄膜材料(S、iGe、Te、灰Se等),以及在光电子领域具有广阔应用前景的各种直接带隙的半导体化合物(GaAs、InSb、ZnTe等)。最后,提出离子液体电沉积方法与模板法相结合,制备Si、Ge纳米线,并可以辅助胶体晶体模板法制备光子晶体,为获得完全带隙的光子晶体材料提供了新的技术路线。     

新型硒化亚锗薄膜太阳能电池

<正>无机化合物薄膜太阳能电池如碲化镉(Cd Te)和铜铟镓硒(CIGS)等电池,因具有材料用量少、产品轻质可柔性、制备能耗低、弱光和高温发电性能好等优势,从而成为太阳能电池中的热点研究领域之一。然而,因为Cd是剧毒元素,且Te、In资源非常稀缺,这些电池的大范围应用具有一定的局限性。近年来,为了降低成本和解决材料丰度问题,铜锌锡硫硒(CZTSSe)太阳能电池受到了极大的关注。该材料中各元素均属于高丰度低成本     

基于纳米材料的固相萃取在痕量元素及其形态分析中的应用

作为新型材料的典型代表,纳米材料具有粒径小、比表面积大、表面原子活性高等优点,已成为一类极具潜力的固相萃取材料,在痕量元素及其形态分析领域得到了广泛的应用.本文对不同类型纳米材料与原子光/质谱相结合在痕量元素及其形态分析中的应用现状进行了评述,包括零维纳米材料(如纳米球、富勒烯、量子点等)、一维纳米材料(如碳纳米管、纳米棒、纳米线等)、二维纳米材料(如纳米纤维、石墨烯/氧化石墨烯、层状双氢氧化物等)及三维纳米材料(如三维碳材料、纳米海绵、树枝状大分子等).为了改善其选择性、拓宽其在不同实际样品中的应用潜力、或进一步提高其吸附容量,一些新型的纳米材料包括离子印迹材料、限制性进入材料、金属有机框架材料等也被用于环境及生物样品中痕量元素及其形态的分析,推动了其在该研究领域的进一步发展.     

含Co或Ni的双金属及三金属纳米颗粒制备方法及其催化制氢性能

常见的氢气储存方法有液态储氢、高压气态储氢、有机化合物储氢、金属氢化物储氢、吸附储氢及液相化学储氢材料储氢等,其中液相化学储氢材料由于具有含氢量高、且可按时即需释放氢气的优点,引起了研究人员的广泛关注;选择合适的催化剂催化液相储氢材料制氢已成为一个研究热点。含有Co或Ni的双金属或三金属纳米颗粒是一种极具应用前景的催化剂,具有价格低廉、储量丰富和催化性能优异等众多优点。本文综述了含Co或Ni的双金属或三金属纳米颗粒的制备方法及其催化制氢性能,并提出了其目前研究中存在的问题和未来潜在的发展方向。     

含Co或Ni的双金属及三金属纳米颗粒的制备方法及其催化制氢性能

常见的氢气储存方法有液态储氢、高压气态储氢、有机化合物储氢、金属氢化物储氢、吸附储氢及液相化学储氢材料储氢等,其中液相化学储氢材料由于具有含氢量高且可按需即时释放氢气的优点,引起了研究人员的广泛关注。选择合适的催化剂催化液相储氢材料制氢已成为一个研究热点。含有Co或Ni的双金属或三金属纳米颗粒是一种极具应用前景的催化剂,具有价格低廉、储量丰富和催化性能优异等众多优点。本文综述了含Co或Ni的双金属或三金属纳米颗粒的制备方法及其催化制氢性能,并提出了其目前研究中存在的问题和未来的发展方向。     

Large-scale synthesis of high-quality ultralong copper nanowires

The present difficulties in synthesis of one-dimensional copper are short length, nonlinear morphology, polydispersivity, poor crystallinity, low yield, and process complexity. In this work, we demonstrate that high-quality ultralong copper nanowires (90-120 nm in diameter, 40-50 microm in length; aspect ratio >350-450) can be synthesized in large scale with a facile aqueous reduction route at low cost. The prepared copper nanowires can also be used as starting solid precursor for fabrication of polycrystalline oxide nanotubes via direct oxidation in air.     

Seedless growth of free-standing copper nanowires by chemical vapor deposition

Free-standing copper nanowires were synthesized by a chemical vapor deposition process at low substrate temperatures using Cu(etac)[P(OEt)3]2 as a precursor. The process requires neither templates nor catalysts to produce copper nanowires of 70-100 nm in diameter, which exhibited high purity and crystallinity with [111] orientation. The grain structures of the films deposited from a series of Cu(I) alkyl 3-oxobutanoate complexes indicated that the high precursor stability was responsible for the columnar growth of the grains, which was evolved to the nanowires eventually.     

Oxidation of Organosilanes with Nanoporous Copper as a Sustainable Non‐Noble‐Metal Catalyst

Although many noble‐metal catalysts have been used for the oxidation of organosilanes, there has been less success with non‐noble‐metal catalysts. Here, unsupported nanoporous copper (np‐Cu) is used to catalyze the oxidation of organosilanes under mild conditions. It is the first time that this reaction has been achieved with a heterogeneous copper catalyst with high activity and selectivity. Both water and alcohols are used as oxidants and the corresponding organosilanols and organosilyl ethers are obtained in high yield. The possible mechanism was obtained by kinetic studies. The catalyst could be reused at least five times without evident loss of activity. As a novel green catalyst np‐Cu should play a unique role in organic synthesis.     

Enrichment,incorporation and oxidation of copper during anodising of aluminium–copper alloys

Porous anodic oxides generated on copper‐containing aluminium alloys are less regular than anodic oxides generated on pure aluminium. Specifically, a porous oxide morphology comprising layers of embryo pores, generated by a cyclic process of oxide film growth and oxygen evolution, is generally observed. In this work, the relation between the oxidation behaviour of copper during anodising and the specific porous oxide film morphology was investigated by electrochemical techniques, transmission electron microscopy and Rutherford backscattering spectroscopy (RBS). It was found that the anodising potential determines the oxidation behaviour of copper, and the latter determines the porous oxide morphology. At low voltage, relatively straight pores with continuous cell walls were obtained on Al? Cu alloys, but selective oxidation of aluminium atoms resulted in the occlusion of copper‐containing metallic nanoparticles in the anodic film. At higher potentials, copper oxidation promoted oxygen evolution within the barrier layer, and generation of a less regular film morphology. RBS, performed on Al? Cu alloy specimens, revealed a high volume fraction of copper atoms in the anodic films generated at low potentials and a reduced amount of copper atoms in the anodic oxide films generated at high potentials. Copyright © 2009 John Wiley & Sons, Ltd.     

An improved sensitivity non-enzymatic glucose sensor based on a CuO nanowire modified Cu electrode

CuO nanowires have been prepared and applied for the fabrication of glucose sensors with highly enhanced sensitivity. Cu(OH)(2) nanowires were initially synthesised by a simple and fast procedure, CuO nanowires were then formed simply by removing the water through heat treatment. The structures and morphologies of Cu(OH)(2) and CuO nanowires were characterised by X-ray diffraction, X-ray photoelectron spectroscopy, scanning electron microscopy, and transmission electron microscopy. The direct electrocatalytic oxidation of glucose in alkaline medium at CuO nanowire modified electrodes has been investigated in detail. Compared to a bare Cu electrode, a substantial decrease in the overvoltage of the glucose oxidation was observed at the CuO nanowire electrodes with oxidation starting at ca. 0.10 V vs. Ag/AgCl (saturated KCl). At an applied potential of 0.33 V, CuO nanowire electrodes produce high and reproducible sensitivity to glucose with 0.49 microA/micromol dm(-3). Linear responses were obtained over a concentration range from 0.40 micromol dm(-3) to 2.0 mmol dm(-3) with a detection limit of 49 nmol dm(-3) (S/N = 3). The CuO nanowire modified electrode allows highly sensitive, low working potential, stable, and fast amperometric sensing of glucose, thus is promising for the future development of non-enzymatic glucose sensors.     

一价铜改性ZSM-5催化剂及其催化碳烟氧化反应性能研究

采用固态离子交换法制备了系列一价铜改性的ZSM-5催化剂,结合多种表征手段,研究了一价铜改性对碳烟氧化反应催化活性的影响。结果表明,采用固态离子交换法可以制备出高负载量的一价铜改性Cu/ZSM-5分子筛催化剂,而不会破坏ZSM-5分子筛原有微孔结构;随催化剂中一价铜比例的增加,低温还原峰和高温还原峰均向低温段移动,且低温还原峰面积增加。改性催化剂对碳烟氧化反应的催化活性随改性元素比例变化先增加后降低;当铜改性比例超过11%后,铜物种的分散性及催化剂对碳烟氧化反应的催化活性均恶化。同时研究还发现,反应气氛中通入NO可以改善催化剂对碳烟氧化反应的催化效果。     

Wet chemical synthesis of Cu/TiO2 nanocomposites with integrated nano-current-collectors as high-rate anode materials in lithium-ion batteries

Using a soft-template assisted method, well-organized Cu/TiO(2) nanoarchitectured electrode materials with copper nanowires as their own current collectors are synthesized by controlled hydrolysis of tetrabutyl titanate in the presence of Cu-based nanowires, and investigated by SEM, TEM, XRD, Raman spectroscopy and electrochemical tests towards lithium storage. Two types of Cu/TiO(2) nanocomposites with different TiO(2) grain sizes are obtained by using different thermal treatments. The two types of Cu/TiO(2) nanocomposites show much enhanced rate performances compared with bare TiO(2). A high-rate capability (reversible capacity at 7500 mA g(-1) still accounts for 58% of its initial capacity at 50 mA g(-1)) is observed for the Cu/TiO(2) nanocomposite with smaller TiO(2) grain size. The improvements can be attributed to the integrated Cu nanowires as mechanical supports and efficient current collectors. A cell made from the Cu/TiO(2) nanoarchitectured electrodes exhibits promise as an energy storage device with both high energy and high power densities.     

Controlled reactions on a copper surface: synthesis and characterization of nanostructured copper compound films

We report the synthesis of nanostructured copper compound films on a copper surface under mild conditions. A series of low-dimensional structures including Cu(OH)(2) fibers and scrolls, CuO sheets and whiskers, and Cu(2)(OH)(2)CO(3) rods have been successfully grown on the copper surfaces at ambient temperature and pressure. Most of the structures are phase-pure single crystallites. The films were formed by the direct oxidation of copper in aqueous solutions of NaOH with an oxidant (NH(4))(2)S(2)O(8). The evolution of the ultrafine structures as a function of the reaction conditions has been revealed, from fibers of Cu(OH)(2) to scrolls of Cu(OH)(2) to sheets or whiskers of CuO. By replacing NaOH with NaHCO(3) in the synthesis, square/rectangular rod arrays of Cu(2)(OH)(2)CO(3) were obtained. The controlled reactions allow the large-scale, template-free, cost-effective synthesis of copper compound films with ordered, uniform, stable, ultrafine structures.     

Preparation and characterization of copper/silver bimetallic nanowires with core‐shell structure

Core‐shell copper/silver bimetallic nanowires were prepared by replacement reaction with citric acid and polyvinylpyrollidone at room temperature. A uniform silver coating was obtained by strictly controlling the molar ratio of Ag/Cu. The copper/silver composite was characterized by X‐ray diffraction, scanning electron microscopy, electron probe microanalysis and X‐ray photoelectron spectroscopy. Microscopic analysis shows that a well‐copper/silver core‐shell structure was formed. Thermo‐gravimetry and differential thermal analysis to the composite nanowires show that the silver coatings efficiently inhibit the oxidation of Cu. Copyright © 2015 John Wiley & Sons, Ltd.     

The role of oxidative etching in the synthesis of ultrathin single-crystalline Au nanowires

The fabrication of ultrathin single-crystal Au nanowires with high aspect ratio and that are stable in air is challenging. Recently, a simple wet-chemical approach using oleylamine has been reported for the synthesis of Au nanowires with micrometer length and 2 nm in diameter. Despite efforts to understand the mechanism of the reaction, an ultimate question about the role of oxygen (O(2)) during the synthesis remained unclear. Here we report that the synthesis of ultrathin Au nanowires employing oleylamine is strongly affected by the amount of O(2) absorbed in the reaction solution. Saturating the solution with O(2) leads to both a high-yield production of nanowires and an increase in their length. Nanowires with diameters of about 2 nm and lengths of 8 μm, which corresponds to an aspect ratio of approximately 4000, were produced. The role of oxygen is attributed to the enhanced oxidation of twin defects on Au nanoparticles formed in the first stage of the reaction. Understanding the role of oxidative etching is crucial to significantly increasing the yield and the length of ultrathin Au nanowires.