静电纺丝法制备NiO纳米纤维及其表征

纳米级NiO因具有优良的催化和热敏等性能而被广泛用于催化剂^[1]、电池电极^[2,3]、光电转化材料^[4～6]、电化学电容器^[7～8]等诸多方面.迄今,已成功地制备出N iO的纳米颗粒^[9]、纳米线^[10]及纳米薄膜^[11],但是对于具有准一维结构的NiO纳米纤维的制备及性能研究尚未见报道.     

三苯基膦：转换硫醇保护的纳米粒子成[Au25(PPh3)10(SR)5Cl2]2+

我们在此报道了一种未曾发现的有趣现象：尽管[Au₂₃(SC₆H₁₁)₁₆]⁻、Au₂₄(SC₂H₄Ph)₂₀ (Ph:苯环)、Au₃₆(TBBT)₂₈ (TBBTH:对叔丁基苯硫酚)、Au₃₈(SC₂H₄Ph)₂₄、混合Au_x(SC₂H₄Ph)_y团簇及3 nm的金纳米粒子有不同的组成、结构、尺寸和保护性硫醇配体,但它们在三苯基膦(PPh₃)作用下,均能统一地经由亚稳的[Au₁₁(PPh₃)₈Cl₂]²⁺最终转化为稳定的双二十面体[Au₂₅(PPh₃)₁₀(SR)₅Cl₂]²⁺ (SR:硫醇配体)。换句话说,三苯基膦是这些硫醇保护的纳米粒子的统一转化器。然而,聚乙烯吡咯烷酮(PVP)/柠檬酸盐(Citrate)保护的金纳米粒子和[Ag₂₅(SPhMe₂)₁₈]⁻ (Me:甲基)在同样的条件下,却不能转化为[Au₂₅(PPh₃)₁₀(SR)₅Cl₂]²⁺或[Ag₂₅(PPh₃)₁₀(SR)₅Cl₂]²⁺,暗示了硫醇保护的金纳米粒子具有与三苯基膦反应的独特性能。另外,我们考察了配体对双二十面体[Au₂₅(PPh₃)₁₀(SR)₅Cl₂]²⁺团簇荧光性能的影响。     

炸药爆轰合成纳米石墨的红外光谱研究

石墨是碳材料中最常见的结晶状态,它具有耐高温、抗腐蚀、自润滑、无毒及价格低廉等特点,广泛应用于润滑剂和添加剂等方面^[1].由于高纯纳米石墨粉在某些高新技术领域中有较好的应用前景,近些年来得到开发和应用,如制成复合导电材料、吸波材料及储氢材料等^[2].以前有学者用纳米金刚石粉加热相转变^[3]和高能球磨^[4,5]的方法制备了纳米石墨,在制备碳纳米管时也有石墨的纳米粒子生成^[6].但用这几种方法制备纳米石墨,既费时又消耗较大能量,成本非常高.     

一系列Ru(II)配合物电致化学发光性质的比较研究

比较研究了以C₂O₄^2－为共反应物时5个结构相关的Ru(II)配合物[Ru(bpy)₂L¹]^2＋, [Ru(bpy)₂L²]^2＋, [Ru(bpy)₂L³]^2＋, [Ru(phen)₂L¹]^2＋和[Ru(phen)₂L²]^2＋(其中bpy＝2,2′-联吡啶, phen＝1,10-邻菲啰啉, L¹＝4-羧基苯基咪唑[4,5-f][1,10]邻菲啰啉, L²＝3-羧基-4-羟基苯基咪唑[4,5-f][1,10]邻菲啰啉, L³＝3,4-二羟基苯基咪唑[4,5-f][1,10]邻菲啰啉)的电致化学发光(ECL)性质. 结果表明, 酚羟基的存在能有效地淬灭Ru(II)配合物[Ru(bpy)₂L²]^2＋, [Ru(bpy)₂L³]^2＋和[Ru(phen)₂L²]^2＋的ECL, 其它Ru(II)配合物的ECL量子效率与[Ru(bpy)₃]^2＋相差不大.     

孔隙结构可调的Cu2O球状纳米结构及其NO2气体传感性质

报道在聚乙烯吡咯烷酮(PVP)的协助作用下,通过简单调节OH^-离子的浓度及Cu²⁺的释放速度,将Cu₂O调节为具有不同空腔特征(介孔、空心及实心)结构的纳米球.研究表明, OH^-根离子的扩散动力学是决定产物结构的关键因素.当[OH^-] > 0.05 mol·L^-1时,高的化学势使其迅速扩散到PVP胶团内部,与吸附在PVP链上的Cu²⁺反应形成Cu(OH)₂,在抗坏血酸(Vc)的还原作用下经过重结晶得到Cu₂O实心球纳米结构;当[OH^-] < 0.025 mol·L^-1时,其扩散速度下降,首先与吸附在PVP胶团外部的Cu²⁺反应形成Cu(OH)₂, Cu(OH)₂的形成阻碍了OH^-离子的向内扩散,形成具有较大空腔(~220 nm)的空心球;当0.025 mol·L^-1 < [OH^-] < 0.05 mol·L^-1时,形成较小空腔(30-60 nm)的空心球.以NH₃水为OH^-缓释源时,虽然OH^-浓度较低,但同时Cu²⁺的浓度也低,胶团外部形成的Cu(OH)₂不足以阻碍OH^-离子的向内扩散,反应过程中NH₃的释放及较低的OH^-浓度阻碍了重结晶的发生,从而形成Cu₂O介孔纳米球.对三种典型结构特征的产物进行了NO₂气体传感性质研究,结果表明, Cu₂O介孔纳米球相比空心结构和实心结构具有更为优异的响应性.结合比表面积数据,我们认为介孔纳米球疏散的结构有利于NO₂气体的扩散和O₂的吸附,从而表现出了更灵敏的气体传感性.     

NiTi过渡金属团簇的结构和芳香性的理论研究

在B3PW91/6-311+G(d)计算水平上, 计算并讨论了Ni₄Ti₂, [Ni₄Ti₂]²⁺, [Ni₄Ti₂]^2-与Ni₄Ti₄, [Ni₄Ti₄]²⁺, [Ni₄Ti₄]^2-团簇的几何结构和芳香性. 在构型优化过程中得到了Ni₄Ti₂(D_4h), [Ni₄Ti₂]²⁺(D_4h), [Ni₄Ti₂]^2-(D_4h)和Ni₄Ti₄(D_2h)4个稳定构型, 发现当引入上下2个Ti原子后, Ni₄环成为了平面正方形构型. 核无关化学位移(NICS)计算结果表明, Ni₄Ti₂(D_4h)与Ni₄Ti₄(D_2h)的NICS值为正, 而[Ni₄Ti₂]²⁺(D_4h)和[Ni₄Ti₂]^2-(D_4h)的NICS值为负, 且[Ni₄Ti₂]^2-(D_4h)的NICS值更负. 同时还发现, 由s与d轨道参与形成的反磁性环流是引起[Ni₄Ti₂]²⁺(D_4h)和[Ni₄Ti₂]^2-(D_4h)具有较大芳香性的主要原因; 其中Ti原子主要提供d_z²与s轨道, 而Ni原子主要利用其d_z²与d_x²-y²轨道形成正方形环, 它们之间构成了球状的d轨道环流, 且[Ni₄Ti₂]²⁺(D_4h)和[Ni₄Ti₂]^2-(D_4h)中还有非常明显的π轨道环流.     

两种卟啉化合物在Ag溶胶表面的紫外-可见吸收光谱和表面增强拉曼散射光谱研究

表面增强拉曼散射(SERS)自1974年被Fleischmann等^[1]发现以来,日益受到人们的重视.通过SERS谱图分析,可以获得物质结构及其与基体作用的信息.由于SERS可使拉曼信号增强10⁵~10⁶倍^[2],并且在某些情况下银胶还能使表面吸附质的荧光猝灭^[3,4], SERS常用来检测一些普通拉曼光谱难以检测的样品和考察界面络合物的形成.     

钙离子体系中隐式和显式内随机共振

近年来, 细胞内钙离子信号及其产生机理已成为研究热点之一, 这是因为钙离子信号能控制细胞的生死、 传递细胞间的信息、 提高基因表达的有效性和特殊性[^1~3]. 在钙离子信号传递过程中, 受环境扰动是不可避免的. Shuai等^[4]发现噪音能够控制钙离子通道中钙离子的释放. 在过去的十年中, 无论是物理、 化学还是生物体系^[5~10]的噪音效应已被广泛研究, 其中包括对随机共振(SR)的研究^[5], 经典SR是环境噪音能够放大弱的外加信号. 但随着研究的深入, 发现有无噪音SR^[11]和内SR(ISR) ^[6]. ISR的内信号来自噪音诱导的内信号, 这种SR现象叫隐式内SR(IISR). 而我们则发现了另外一种内SR, 即显式内SR(EISR) ^[12], 它的内信号是体系固有的内信号, 而不是由噪音诱导的. 本文主要研究加入外信号将对IISR和EISR产生的影响.     

锌-稀土矩形纳米簇的构筑及近红外发光性能

本文设计了一个新型含苯-甲基-苯骨架的席夫碱配体,构筑了两个具有矩形结构的锌-稀土纳米簇[Ln₂Zn₂L₂(OAc)₆] (Ln = Yb (1)和Er (2))。该席夫碱配体以“伸展型”配位模式与稀土离子进行配位,使这些锌-稀土纳米簇表现出较大的分子尺寸结构(0.7 nm × 1.1 nm × 2.2 nm)。荧光性质研究表明,由Zn/L组成的发色基团能有效敏化1和2中Yb³⁺和Er³⁺离子的近红外发光。通过对荧光量子产率及寿命进行分析发现,Zn/L对Yb³⁺离子的传能效率要高于Er³⁺离子。     

硒化铜/硒化锌复合物的制备及性能表征

<正>硒化物半导体具有可控的形貌和相结构，在热电、激光、光学滤波器、太阳能电池和传感器等领域有着广泛应用。1996年，美国劳伦斯利弗莫尔国家实验室的研究人员首次提出并验证了过渡金属元素表面掺杂Ⅱ-Ⅵ族半导体晶体作为中红外激光增益介质的可能性。经过表面修饰的Ⅱ-Ⅵ族半导体材料具有优异的中红外光学性能，已经投入工业生产^[1]。2000年，铜掺杂硒化锌(Cu:ZnSe)半导体纳米晶体被首次报道(量子产率2%～4%)^[2]。2005年，彭笑刚团队^[3]将掺杂方法分为生长掺杂和成核掺杂两种，并采用生长掺杂法制备了高质量的Cu:ZnSe量子点(量子产率10%～30%)，该量子点会发出明亮的翠绿色光。然而，上述材料的合成路线对环境有害，在生物医药领域并不适用。2006年，中国科学院某实验室采用宽带隙的ZnSe修饰硒化镉(CdSe)纳米粒子，可以有效地去除CdSe表面缺陷^[4]。     

Massenspektrometrische untersuchungen zur elementaranalyse organischer verbindungen—III: Verbrennungsvorgänge im leeren rohr

A measuring system is described which permits study of all stages of combustion processes as functions of carrier gas, temperature, residence time and tube filling. The organic sample is fed at constant speed into a stream of carrier gas. The mixture reaches the combustion chamber within a few milliseconds via a transfer capillary. With the help of a viscous inlet system, a sample of the resulting reaction products is taken and fed into a mass spectrometer. Reaction time and temperature can be adjusted within wide ranges or varied continuously. A plot of the extent of reaction of the various combustion products against temperature at a chosen reaction time yields an oxidation-thermogram which gives a clear picture of the combustion process. It is evident from thermograms of selected compounds that the samples decompose in the presence of oxygen at appreciably lower temperatures than in inert gas. The primary step of the decomposition is “oxidative pyrolysis” which often leads to other products than “inert pyrolysis”. The intermediate products found are partly structurally specific and, especially with nitrogen-containing samples, are numerous and long-lived (for example, carbon monoxide, nitric oxide, cyanogen, hydrocyanic acid, cyanic acid and methyl cyanate). The notorious “difficult combustibility” is largely due to the fact that carbon monoxide, cyanic and hydrocyanic acids undergo complete combustion only at very high temperature. The combustion properties of the “empty tube” can be improved noticeably by a filling of quartz wool and markedly by partly filling with platinum wool.     

A method of obtaining a small number of nucleation sites and growing large crystal grains

Optical microscopy was used in situ for the investigation of granular metal growth in electrochemical depositions of silver from a silver nitrate solution on a glassy carbon substrate. Incomplete dissolution of silver upon anodic polarization was observed and explained in terms of “undercutting”. A triple potentiostatic (or galvanostatic) pulse technique was developed for obtaining a small number (between 1 and 10) of nuclei in the field of vision, and growing them into large crystal grains. The pulse train consists first of a negative pulse to deposit silver crystallites, then a positive one to dissolve them all, but a few, which then serve as sites for growth in the third negative step.     

The Oxidation of Aliphatic Hydrocarbons in the Presence of Higher Oxidation States of Silver

Abstract

The compound silver “peroxide”? has been known for some time and its preparation is described in the literature.¹ The structure of this compound has been in dispute; however it appears to have been resolved using neutron diffraction techniques. Scatturin, Bellon and Salkind² have shown that silver “peroxide” is a rather complex material in which silver is present in two different oxidation states, namely Ag(I) and Ag(III). In the crystal, Ag(III) atoms are coordinated to oxygen in a square planar array and the Ag(I) atoms are linearly coordinated. There are no peroxide oxygens. Hence the formula for silver “peroxide” is more properly written Ag(I)Ag(III)02.     

Silver Nanowires as Templates for Preparation of Amorphous Carbon Nanotubes

In this report, we describe a novel method for preparing amorphous carbon nanotubes (ACNT) from silver nanowires using a carbon replica technique. ACNT size and shape are determined by the template silver nanowire. Interspaces between carbon grains present in the ACNT wall cause the wall to act as a permeable membrane through which reactants pass freely. Simple chemical modifications can be used to modify the diameter of the silver filaments within. We anticipate that this method will prove useful in preparing a wide variety of nanometer-sized filaments, perhaps with the replica itself able to serve as a template in casting nanomaterials of assorted shapes. Copyright 2000 Academic Press.     

Salvaging Reactive Fullerenes from Soot by Exohedral Derivatization

The awesome allotropy of carbon yields innumerable topologically possible cage structures of molecular carbon. This field is also related to endohedral metallofullerenes constructed by metal‐atom encapsulation. Stable and soluble empty fullerenes and endohedral metallofullerenes are available in pure form in macroscopic amounts from carbon arc production or other physical processes followed by extraction and subsequent chromatographic separation. However, many other unidentified fullerene species, which must be reactive and insoluble in their pristine forms, remain in soot. These “missing” species must have extremely small HOMO–LUMO gaps and may have unconventional cage structures. Recent progress in this field has demonstrated that reactive fullerenes can be salvaged by exohedral derivatization, which can stabilize the reactive carbon cages. This concept provides a means of preparing macroscopic amounts of unconventional fullerenes as their derivatives.     

Atomic resolution electron microscopy of small metal clusters

Atomic resolution imaging of cluster structures has been performed with high resolution transmission electron microscopy (HRTEM). Metal particles of the sizes 1 nanometer to tens of nanometers have been surface profile imaged on different supports; like zeolites, cordierite and amorphous carbon. It is shown that organic ligands in Schmid-clusters coordinated to the metal surface are desorbed or destroyed by the electron beam. Dynamic events on the surfaces and in the bulk of small metal particles have been recorded for small crystals of Au, Pt, Rh and Pb and can be classified under three headings; The smaller the crystals are the faster rearrangements of the crystal structure; “clouds” of atoms existing outside some surfaces are involved in extensive structural rearrangements of the surface or crystal surface growth; localized atom hopping on surfaces during crystal growth and desorption also occurs.     

The Transannular Interaction in [2.2]Paracyclophane: Repulsive or Attractive?

The molecular structure and charge density distribution in the crystal of [2.2]paracyclophane derived from the high‐resolution single crystal X‐ray diffraction data at 100 K is reported together with ab initio calculations of this molecule. Analysis of the atomic, anisotropic displacement parameters in a “rigid‐body” model approximation has revealed that the molecule is ordered in the crystal. Topological analysis of the electron density and potential‐energy density‐distribution functions has demonstrated that there is no “through‐space” interaction between the rings in the molecule. The role of the ethylene bridges and distortion of the aromatic desks on the inter‐ring interaction are discussed.     

Ag Nanocomposite Particles: Preparation,Characterization and Application

Summary Herein, we report that different core-shell particles could be successfully used as the carrier systems for the deposition of silver nanoparticles. Firstly, thermosensitive core-shell microgel particles have been used as the carrier system for the deposition of Ag nanoparticles, in which the core consists of poly (styrene) (PS) whereas the shell consists of poly (N-isopropylacrylamide) (PNIPA) network cross-linked by N, N′-methylenebisacrylamide (BIS). Immersed in water the shell of these particles is swollen. Heating the suspension above 32 °C leads to a volume transition within the shell, which is followed by a marked shrinking of the network of the shell. Secondly, “nano-tree” type polymer brush can be used as “nanoreactor” for the generation of silver nanoparticles also. This kind of carrier particles consists of a solid core of PS onto which bottlebrush chains synthesized by the macromonomer poly (ethylene glycol) methacrylate (PEGMA) are affixed by “grafting from” technique. Thirdly, silver nanoparticles can be in-situ immobilized onto polystyrene (PS) core-polyacrylic acid (PAA) polyelectrolyte brush particles by UV irradiation. Monodisperse Ag nanoparticles with diameter of 8.5 nm, 7.5 nm and 3 nm can be deposited into thermosensitive microgels, “nano-tree” type polymer brushes and polyelectrolyte brush particles, respectively. Moreover, obtained silver nano-composites show different catalytic activity for the catalytic reduction of p-nitrophenol depending on the carrier system used for preparation.     

Application of the Kelvin equation to vaporization of silver and gold in electrothermal atomic absorption spectrometry

In order to obtain additional insight into the release mechanism of the metals in electrothermal atomization atomic absorption spectrometry, a quantitative relation between the heat of vaporization and the size of the released particles is proposed on the basis of the Kelvin equation. The applicability of the equation for the investigation of silver and gold vaporization is demonstrated and the limits in which the model is valid are determined.According to the present considerations the activation energy could be equal to the heat of vaporization of the silver and gold droplets. An explanation of the observed dependence of activation energy on analyte mass is given. The proposed relation provides a possibility for definition and evaluation of an “effective” radius/size of the droplets on the basis of their heat of vaporization. A correlation between the mass of the injected sample and the “effective” radius of the droplets, obtained at higher temperature is found. The minimum and maximum “effective” radii of the droplets, following the proposed equation are calculated for Ag on pyrolytic graphite coated electrographite (PGC) and Au on PGC, uncoated electrographite (EG) and glassy carbon (GC) tubes. The results obtained are indirect evidence for the island structure of precursor metal layer and for the existence of silver and gold microdroplets on the graphite support.