银纳米线的制备及电催化还原氧性能研究

分别以聚乙烯基吡咯烷酮(PVP),乙二醇作为软模板和还原剂,采用不同晶种(AgCl、Ag)快速合成了银纳米线.通过SEM和TEM表征,证明合成银纳米线材料形貌均一,颗粒含量很少.并且发现以AgCl为晶种合成的银纳米线长径比为200左右(SNWH),而以Ag为晶种合成的长径比为30左右(SNWL).以银纳米线作为电催化氧...     

醇热法合成单晶银纳米线及其表征

以硝酸银为前驱物, 聚乙烯醇缩丁醛(PVB)为结构导向剂, 通过醇热法, 反应温度为140 ℃, 反应时间为24 h的条件下制备了银纳米线. 采用X射线衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)、热重分析(TG)、红外光谱(FT-IR)和激光拉曼光谱(Raman)等手段对产物进行了系统表征, 结果表明: 所得银纳米线具有面心立方结构, 沿着(111)晶面生长, 具有单晶结构; 考察了反应温度和时间对产物形貌的影响, 结果表明: 反应温度和时间在形成银纳米线的过程中起着关键的作用; 银纳米线具有较强的表面增强拉曼散射效应; 同时提出了银纳米线可能的晶化机理.     

纳米结构MnO2的水热合成、晶型及形貌演化

以水热合成方法制备了具有不同微观形貌的纳米结构MnO2, 并以X射线衍射(XRD), 扫描电镜(SEM)和X射线光电子能谱(XPS)等方法对其进行了表征. 跟踪考察了二氧化锰的晶型及微观形貌随水热反应时间的演变过程, 在Ostwald ripening机理作用下, MnO2晶型转化过程为γ-MnO2, α-MnO2和β-MnO2, 同时形貌由微米球转变为海胆结构、空心海胆结构和纳米线.     

修饰晶种法合成MFI型分子筛膜包覆的活性炭颗粒

由于分子筛膜的分离和催化作用, 分子筛膜包覆的传统催化剂颗粒可以实现高效的催化过程. 活性炭颗粒作为一种常用的催化剂载体, 由于其表面的憎水性和不平整, 在不规则活性炭颗粒表面直接水热合成包覆一层分子筛膜非常困难. 为了克服上述缺点, 本文采用一种勃姆石凝胶修饰的晶种法在活性炭颗粒表面合成连续的分子筛膜. 以勃姆石溶胶为前驱体, 在活性炭颗粒表面通过喷涂预先形成一层相对平整的勃姆石凝胶层以改善活性炭表面. 在随后的晶种涂覆过程中, 晶种分散液加入部分勃姆石溶胶为胶粘剂, 所得的晶种层覆盖载体完全, 与载体结合牢固, 无需焙烧处理. 将晶种涂覆后颗粒在旋转动态水热175℃处理6 h, 得到分子筛膜包覆的活性炭颗粒, 所得材料分别用X射线衍射和扫描电镜进行表征. 包覆的分子筛膜为MFI 结构, 厚度约为5μm. 对比实验表明, 没有勃姆石溶胶修饰的活性炭颗粒上不能成膜. 这种勃姆石凝胶修饰晶种法为在各种惰性载体上合成分子筛膜提供了便捷的方法.     

钕的氢氧化物和氧化物纳米线的制备及表征

以金属钕为起始原料，采用简单的碱性溶液下水热法制备出氢氧化钕纳米线。所得到的水热产物采用X-射线衍射、扫描电镜和透射电镜等进行了结构与形态表征。研究发现，水热处理的温度、碱液浓度和碱的种类等对水热产物的形貌、长径比和结晶状态有较大影响，提高水热温度和增加碱液浓度有利于氢氧化钕纳米线的生长。在相同水热反应温度(180 ℃)、水热时间(45 h)和碱浓度下，5 mol·L^-1 NaOH溶液体系制备的氢氧化钕纳米线具有较高纯度和较长的长径比，其直径为20～40 nm，长度为2～10 μm。该氢氧化钕纳米线在空气气氛下500 ℃烧结后形成具有体心立方结构的C型Nd₂O₃，该Nd₂O₃仍具有一维纳米线形貌。升高焙烧温度时产物的形貌和相结构都发生了明显变化。     

软化学法低温合成银纳米线及其生长机制

以AgNO_3为起始物，采用DMF为溶剂和还原剂，无须采用晶种，在低温下 AgNO_3经DMF还原，通过软化学法合成了结构均匀的银纳米线，其直径为15-30nm， 长度高达20μm。通过引入乙酰丙酮，控制钛酸丁酯水解形成的多孔氧化物溶胶为 网络孔道结构，这种孔道结构为银纳米线的控制合成提供了有效的生长模板。     

聚乙烯吡咯烷酮辅助的水热法合成形貌可控的银纳米结构

以不同平均分子质量的聚乙烯吡咯烷酮(PVP,通常用K值来表示PVP溶液相对粘度的特征值,粘度越大,PVP平均分子质量越大,平均分子质量为8000、40000、160000、360000的PVP分别标记为K17、K30、K60、K90)为表面活性剂,通过水热法合成了形貌和光学共振峰可控的银纳米结构.将反应体系加入到60 mL的不锈钢高压反应釜中,在一定的温度下加热数小时.我们在K17的水溶液中合成了尺寸均一的五重孪晶银纳米十面体.而在K30、K60和K90的乙二醇(EG)溶液中得到了纵横比随着PVP分子质量增大而增大的银纳米线.产物的形貌和微结构通过透射电镜(TEM)和场发射扫描电镜(FE-SEM)进行表征,表面等离子共振(SPR)吸收峰通过紫外-可见分光光度计进行测试,结果显示银纳米结构的表面等离子共振随着其形貌和尺寸的改变而发生变化.     

聚乙烯吡咯烷酮辅助的水热法合成形貌可控的银纳米结构（英文）

以不同平均分子质量的聚乙烯吡咯烷酮(PVP,通常用K值来表示PVP溶液相对粘度的特征值,粘度越大,PVP平均分子质量越大,平均分子质量为8000、40000、160000、360000的PVP分别标记为K17、K30、K60、K90)为表面活性剂,通过水热法合成了形貌和光学共振峰可控的银纳米结构.将反应体系加入到60 mL的不锈钢高压反应釜中,在一定的温度下加热数小时.我们在K17的水溶液中合成了尺寸均一的五重孪晶银纳米十面体.而在K30、K60和K90的乙二醇(EG)溶液中得到了纵横比随着PVP分子质量增大而增大的银纳米线.产物的形貌和微结构通过透射电镜(TEM)和场发射扫描电镜(FE-SEM)进行表征,表面等离子共振(SPR)吸收峰通过紫外-可见分光光度计进行测试,结果显示银纳米结构的表面等离子共振随着其形貌和尺寸的改变而发生变化.     

一种新型聚集诱导发光的片状银纳米簇聚集体的合成

具有聚集诱导发光的片状银纳米簇聚集体在生物传感、生物成像等多个领域表现出良好的应用前景。以D-青霉胺(RSH)为配体，在室温下和硝酸银反应，以高产率96%合成了银纳米簇聚集体，并通过红外光谱、X-射线光电子能谱、热重分析、质谱、X-射线衍射、扫描电镜和透射电镜对其结构进行了表征。结果表明：银纳米簇聚集体是银纳米簇通过氢键网络连接形成的微米尺度的片状结构，化学组成是(AgSR)_n。紫外可见吸收光谱和发光光谱研究发现，银纳米簇聚集体最大吸收波长在253 nm,最大发射波长在564 nm;在相同浓度下，银纳米簇聚集体的水溶液不发光，但随着乙醇体积分数的增加，发光逐渐增强，显示出聚集诱导发光行为。     

从Mn_3O_4前驱体到MnO_2纳米结构的形貌和结构变化(英文)

锰氧化物是一类重要的且具有广泛应用背景的材料,控制合成不同形貌和组成的锰氧化物纳米结构将有助于拓宽其应用领域.本文报道了以Mn3O4为前驱体,通过水热法控制合成MnO2纳米结构的方法.用X射线衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)等手段对产物进行表征.在硫酸体系中,当反应温度为80和180℃时,所得产物分别为γ-MnO2海胆结构和β-MnO2单晶纳米棒.此外,MnOOH纳米线可以在稀酸溶液中合成.考察了反应温度、溶液酸度、反应时间对产物结构的影响,并提出了基于γ-MnO2为中间产物的反应机理.实验结果表明,水热体系促进了产物的各向异性生长并最终形成不同形貌和结构的锰氧化物.     

Low-temperature synthesis of single crystalline Ag2S nanowires on silver substrates

We report on the successful synthesis of silver sulfide (Ag(2)S) nanowires by a simple and mild gas-solid reaction approach. For the nanowire synthesis, a preoxidized silver substrate is exposed to an atmosphere of an O(2)/H(2)S mixture at room temperature or slightly above. The resulting Ag(2)S nanowires are phase pure with a monoclinic crystal structure and have diameters of a few tens of nanometers and lengths up to 100 mum. The influence of reaction conditions on the diameter, length, and morphology of the Ag(2)S nanowires has been studied by a number of structural and spectroscopic techniques. The nanowire growth mechanism on the Ag substrate has been discussed, which is likely characterized by continuous deposition at the tip. Additionally, we demonstrate thinning and cutting of individual Ag(2)S nanowires with electron beams and laser beams, which are potentially useful for nanowire manipulation and engineering.     

Room temperature synthesis of silver nanowires from tabular silver bromide crystals in the presence of gelatin

Long silver nanowires were synthesized at room temperature by a simple and fast process derived from the development of photographic films. A film consisting of an emulsion of tabular silver bromide grains in gelatin was treated with a photographic developer (4-(methylamino)phenol sulfate (metol), citric acid) in the presence of additional aqueous silver nitrate. The silver nanowires have lengths of more than 50 μm, some even more than 100 μm, and average diameters of about 80 nm. Approximately, 70% of the metallic silver formed in the reduction consists of silver nanowires. Selected area electron diffraction (SAED) results indicate that the silver nanowires grow along the [111] direction. It was found that the presence of gelatin, tabular silver bromide crystals and silver ions in solution are essential for the formation of the silver nanowires. The nanowires appear to originate from the edges of the silver bromide crystals. They were characterized by transmission electron microscopy (TEM), SAED, scanning electron microscopy (SEM), and powder X-ray diffraction (XRD).     

银纳米线的TEM表征

通过交流电沉积的方法,以多孔铝阳极氧化膜（Al2O3/Al）为模板,制备金属银纳米线.透射电子显微镜（TEM）分析表明, 银纳米线长度平均约为5 μm, 直径25 nm；银纳米线在多孔Al2O3/Al孔内互相平行,显示凸凹相间的条纹结构.选区电子衍射（SAED）证实,银纳米线具有面心立方（FCC）的多晶结构,探讨了银纳米线凸凹相间条纹结构的形成机理.     

Large-scale synthesis of silver nanowires and platinum nanotubes

Silver nanowires have been synthesized by ethylene glycol reduction of silver nitrate with the assistance of polyvinyl pyrrolidone and sodium sulfide in a large scale. By adjusting the reaction temperature and Na₂S content, silver nanowires with lengths up to 3?4 μm can be achieved in high yield. Scanning electron microscopy, transmission electron microscopy (TEM), high-resolution transmission electron microscopy (HRTEM), selected areas electron diffraction (SAED), and X-ray diffraction (XRD) have been employed to characterize silver nanowires. Platinum nanotubes with length about 3 μm can be prepared using as-prepared silver nanowires as sacrificial templates. Platinum nanotubes were characterized by TEM, SAED, and HRTEM.     

氧化铝模板中Ag纳米线阵列的选择性生长

利用Ag离子与Br离子之间的化学沉积作用在孔隙中充满明胶的阳极氧化铝(AAO)模板中制备了AgBr/AAO纳米介孔复合材料.材料选择性曝光后,利用原位显影液对其进行化学显影,在AAO模板中选择性得到Ag纳米线阵列.实验结果表明:Ag纳米线是连续的、致密的,且具有多晶结构,充满了曝光部分的模板孔隙.本文还对影响Ag纳米线选择性生长的因素进行了简单讨论.     

线状和树枝状银纳米结构、形成机理及表面增强拉曼散射性质(英文)

以聚丙烯酰胺(PAM)为模板,在液相中通过不同浓度的抗坏血酸还原硝酸银能够得到缠结的线状和树枝状银纳米结构.该方法合成条件温和(常温常压)、产率高、成本低、操作简单,并且得到了特殊形貌的缠结收光在谱一对起线的状线和状树银枝纳状米银结纳构.米通结过构透的射形电貌子和显性微质镜进(T行E了M)表,扫征描.研电究子表显明微,镜PA(SMEM对)线、拉形曼产光物谱的和形紫成外起?可了见决吸定性作用.在反应初期,大量新生成的银核被PAM链吸附,小颗粒逐渐长大,进而相连,导致生成了缠结的线状银纳米结构.另外,抗坏血酸的浓度越高,越不利于线状结构的生成.利用对巯基苯胺(PATP)为探针分子研究了银纳米结构的表面增强拉曼散射(SERS)活性,结果表明线状银纳米结构具有较强的表面增强拉曼散射效果.     

Synthesis and characterization of silver nanowires with zigzag morphology in N,N-dimethylformamide

Zigzag silver nanowires with a uniform diameter of 20±5 nm were prepared by reducing silver nitrate (AgNO₃) with N,N-dimethylformamide (DMF) in the presence of tetrabutyl titanate (TBT) and acetylacetone (AcAc) at 373 K for 18 h. X-ray and selected area electron diffraction (XRD and SAED) patterns reveal that the prepared product is made of pure silver with face centered cubic structure. Transmission electron microscopy (TEM) investigations suggest that the amount of silver nanowires is enhanced with increase in reaction time, and the end-to-end assemblies of silver nanorods are observed during the reaction process. After 18 h reaction, silver nanowires with zigzag morphology are obtained. In this paper, a possible growth process of silver nanowires with this interesting shape is described. Silver nanoparticles with small sizes were obtained by reducing Ag⁺ ions with DMF, providing seeds for homogeneous growth of silver nanorods. With the extending reaction time, the synthesized silver nanorods were connected in an end-to-end manner, and the interface between the connections of two nanorods gradually disappeared. The final product shows zigzag morphology with various angles. The angles between two connecting straight parts of zigzag nanowires exhibit an alterable range of 74-151°. These silver nanowires show tremendous potential applications in future nanoscale electronic circuits.     

A simple hydrothermal route to large-scale synthesis of uniform silver nanowires

This paper describes the preparation of uniform silver nanowires by reducing freshly prepared silver chloride with glucose at 180 degrees C for 18 hours in the absence of any surfactants or polymers. Scanning electron microscopy studies indicated that the silver nanowires are about 100 nm in diameter and up to 500 microm in length. High-resolution transmission electron microscopy analyses showed that the silver nanowires grow perpendicularly to the Ag(200) plane. The silver nanowires are believed to grow through a solid-solution-solid process. Some influential factors on the growth of silver nanowires are also discussed.     

A Simple Hydrothermal Route to Large‐Scale Synthesis of Uniform Silver Nanowires

This paper describes the preparation of uniform silver nanowires by reducing freshly prepared silver chloride with glucose at 180 °C for 18 hours in the absence of any surfactants or polymers. Scanning electron microscopy studies indicated that the silver nanowires are about 100 nm in diameter and up to 500 μm in length. High‐resolution transmission electron microscopy analyses showed that the silver nanowires grow perpendicularly to the Ag(200) plane. The silver nanowires are believed to grow through a solid–solution–solid process. Some influential factors on the growth of silver nanowires are also discussed.