酞菁锌衍生物L-B膜的光电性能研究

用L-B膜方法在SnO₂电极上修饰了不同链长烷氧基取代的酞菁锌化合物(ZnPc C_nH_2n+1,n=3,9,12,16),分别研究了它们单分子膜成膜性能和转移性能,并测定了修饰在SnO₂电极上的单多层分子膜的光电性能和吸收光谱。研究结果指出链短的取代基即异丙氧基取代的酞菁锌(ZnPcC₃H₇(i))具有较高的转移比及较好的光电性能。     

SnO2TiO2 复合半导体纳米薄膜的研究进展*

本文概述了SnO₂TiO₂ 复合半导体纳米薄膜的发展历史和研究现状,对比分析了“混合”、“核壳”和“叠层”3 种复合薄膜的结构和性能特点,着重论述了叠层结构的SnO₂ /TiO₂复合薄膜的光电化学和光催化特性。结合作者的研究工作,探讨了SnO₂ /TiO₂双层复合薄膜上下层厚度对其光催化活性的影响,指出复合薄膜光催化活性的提高可归因于电子从TiO₂ 向SnO₂ 的迁移。最后对SnO₂ /TiO₂复合薄膜的局限性和发展潜势做一简要分析,强调了该复合薄膜本身的应用特点。     

硬脂酸二茂铁酯L-B膜修饰SnO2电极的阻抗研究

测定了二茂铁衍生物——硬脂酸二茂铁酯L-B膜修饰SnO₂电极在Fe(CN)₆^3-/4-溶液中的阻抗性能,用单纯形法求出了等效电路中的元件参数值,计算了电极反应速度常数K_s。从分析SnO₂电极修饰不同层的硬脂酸二茂铁酯L-B膜的界面阻抗和电极反应的动力学性能,表明与在固相中研究的硬脂酸二茂铁酯L-B膜的阻抗性能明显不同,在Fe(CN)₆^3-/4-溶液中表现了电活性分子修饰电极的界面阻抗行为,进一步证实了修饰在SnO₂电极上的硬脂酸二茂铁酯L-B膜在Fe(CN)₆^3-/4-的氧化还原电极反应过程中,起电荷传递的中介作用。     

硬脂酸二茂铁酯L-B膜的电化学性能研究

本文研究二茂铁衍生物——硬脂酸二茂铁酯(FcOCOC₁₇H₃₅)L-B膜技术修饰SnO₂电极的循环伏安性能.实验结果用电极表面吸附(修饰)分子的表面活度理论进行计算机拟合和此较,实验数据与理论符合较好.进一步求得修饰分子的标准电极电势和修饰量。结果表明硬脂酸二茂铁酯L-B膜电化学性能稳定,可逆性较好,可以作为快速电荷转移的修饰电极材料。     

掺杂Eu2O3的SrTiO3及SnO2光致发光

用具有大能隙的本征半导体(SrTiO₃及SnO₂)粉末作本体,分别掺杂1%(原子百分数)的Eu₂O₃;所得物质表现出Eu³⁺离子的线发射光谱特性,但相对发光强度及光谱形状有相当大的变化。X射线衍射结构分析显示Eu³⁺在SrTiO₃晶格里是处在间隙位置,而它在SnO₂晶格里则形成新物相Eu₂Sn₂O₇。     

烧成温度对气敏材料性能的影响

选用SnO₂-ZrO₂和SnO₂-ThO₃体系作为气敏材料,研究了烧成温度对材料结构和粒度的影响。分别用以上体系制成气敏元件,研究了烧成温度对气敏材料的灵敏度和选择性的影响,结果发现,在本实验条件下,烧成温度不但影响材料的灵敏度,对材料的选择性也有很大的影响。     

Cr(Ⅲ)盐在Pt电极和PbO电极上阳极氧化为铬酸盐的机理的研究

在[H₂SO₄]和[SO₄^2-]恒定的不同浓度Cr₂(SO₄)₃溶液中测定了Cr³⁺在光滑Pt和PbO₂电极上的稳态极化曲线和分解极化曲线,得到了氧的阳极发生和Cr⁶⁺阳极形成的动力学数据,提出了Cr(Ⅵ)是由Cr(Ⅲ)通过"活性氧"的氧化形成的反应机理。测得了PbO₂电极上不同过电位下电极反应的有效活化能,其数值均在41.9kJ/mol以上,且随着极化的增大而减小,据此在动力学处理中可以忽略扩散的作用。测得了在不同电位极化下PbO₂电极的阻抗频谱。在较高电位下阻抗谱呈现明显的两个半圆,表明电极过程包括了中间吸附物的形成。吸附电容C_ad比双层电容C_d大1-2个数量级;C_d比通常光滑电极表面的C_d大得多,这可能与阴离子的特性吸附有关。     

磺化酞菁类染料光敏氧化胆固醇及L-半胱氨酸的反应

本文合成了磺化酞菁、磺化酞菁镓和磺化酞菁铝,研究了它们光敏氧化胆固醇及L-半胱氨酸的反应。染料的聚集态和溶液的pH值对反应速率有不同程度的影响。D₂O加速反应而NaN₃猝灭反应的结果表明,光敏氧化反应主要通过Ⅱ型(涉及¹O₂)机制进行。     

一种新型半导体气体传感器

气体传感器的结构形式通常有接触燃烧型、陶瓷烧结型和气敏感场效应晶体管型等。陶瓷烧结型的传感方式是基于金属氧化物半导体(如SnO₂、ZnO和γ-Fe₂O₃)吸附气体分子后表面电阻发生变化的原理来实现的^(1-3)。     

以共价键相连的卟啉-酞菁化合物分子内能量传递及光诱导电子转移

合成了叶啉与酞菁以共价键连接起来的双发色团分子。测定了它们的吸收光谱,荧光光谱,荧光寿命等。计算了分子内能量传递过程的效率(φ_EnT)及速率常数(κ_EnT)。结果表明:在稀溶液中,卟啉与酞菁等克分子混合时,观察不到分子间能量传递过程现象的发生;而双发色团分子的分子内能量传递过程则明显发生了,其效率(φ_EnT=13～70%)与速率常数(κ_EnT=1.2×10⁷～2.0×10⁸s^-1)取决于分子的结构类型。电子转移与能量传递过程与介质性质有关。在极性溶剂中有利于电子转移过程的进行,而不利于能量传递过程;在非极性溶剂中,则有利于能量传递过程的进行,而不利于电子转移。 选择性激发酞菁发色团,观测到了只有电子转移发生的过程,其电子转移效率达到38%。     

Ion-Exchange Chromatographic Supports Obtained by Formation of Polyelectrolyte Multi-Layers for the Separation of Proteins

Summary High performance liquid chromatography (HPLC) was used to study the mechanism of formation of polyelectrolyte multilayers on porous silicas. The coatings were produced by alternating the adsorption of positively and negatively charged polymers. The stationary phases formed by adsorbing a single layer, double layers and triple layers were tested by studying the elution behavior of model proteins. The double polymer coating was achieved by adsorbing first a polycation such as hexadimethrine bromide (HB) on the HPLC silica support and then a polyanion such as dextran sulfate (DS) on the cationic layer formed. The retention properties of this support are mainly those of a cation exchanger as the negatively charged proteins were strongly retained while positively charged ones were weakly adsorbed. This work demonstrated the importance of the first underlying layer as the retention behavior of proteins was greatly affected by the properties of this coating. The triple polymer coating was achieved by adsorbing the polycation (HB) on the double layer coating (HB-DS). Its retention behavior was that of an anion exchange support. The HB-DS stationary phase displayed good chromatographic performances, with an adsorbed layer relatively stable. The polyelectrolyte multilayer coating procedure was useful to easily synthesize cation-exchange supports for the separation of basic proteins.     

ZnS/SiO2协同包覆光阳极制备高效率Zn-Cu-In-Se量子点敏化太阳能电池

通过光阳极协同包覆的策略抑制Zn-Cu-In-Se(ZCISe)量子点敏化太阳能电池(QDSC)中光阳极/电解液界面上的电荷复合过程,提高电荷收集效率和电池光伏性能。采用溶液法在ZCISe量子点敏化的光阳极表面依次沉积包覆ZnS和SiO₂双钝化层,实现较单一ZnS包覆层更有效的界面电荷复合抑制作用,从而提高QDSC的性能。在包覆ZnS/SiO₂双钝化层后,所组装的ZCISe QDSC光电转换效率由传统单一ZnS包覆的12.17%提高到13.23%,这归因于双钝化层对光阳极/电解液界面电荷复合过程的有效抑制,电荷收集效率得到相应提升。     

Acrylic acid copolymer nanoparticles for drug delivery. Part II: Characterization of nanoparticles surface-modified by adsorption of ethoxylated surfactants

Copolymer nanoparticles of acrylic acid, acrylic amide, acrylic butylester, and methacrylic methylester with increasing content of acrylic acid were produced and surface-modified by adsorption of nonionic (Poloxamer 407, Poloxamine 908, Antarox CO 990) and ionic (Gafac RE 960) surfactants. The coated particles were characterized with regard to parameters relevant for the in vivo organ distribution: coating layer thickness, charge-reducing effect of the coating layer and surface hydrophobicity. Gafac was found to form highly charged surface layers leading to recognition by the reticuloendothelial system (RES). The hydrophobicity of the coating layers decreased with increasing thickness. The thickest coating layers were found on the most hydrophobic particles possessing least content of acrylic acid (1.9%). These particles coated with the nonionics were regarded as sufficiently hydrophilic to potentially reduce the uptake by the RES in vivo. The properties of coating layers can therefore be optimized by variation of the monomer ratios in copolymers.     

Sol–gel titania coating on unmodified and surface-modified polyimide films

Sol–gel coating of metal oxides on polymer substrates is a useful process to fabricate various organic–inorganic hybrid materials under mild conditions. However, this process is hardly applicable to pristine polyimide (PI) films because their surfaces do not display effective functional groups for metal oxide coatings. In this study, we firstly examined direct sol–gel coating of titania thin layers on unmodified PI film surfaces. The results confirmed homogeneous, ultrathin titania layer coating and showed that the thickness and microscopic morphology of the titania layers were affected by titanium alkoxide concentrations in the spin coating solutions. We next investigated titania layer coating on surface-modified PI films that prepared using alkaline hydrolysis, which generated carboxylic acid groups on the film surfaces. Optimal hydrolysis time was determined using FT-IR spectroscopy and contact angle measurements. After sol–gel titania coating on the hydrolyzed PI film surfaces, the Scotch tape test was conducted to evaluate adhesion strength between the titania layers and PI film surfaces. Morphological observations of the sample surfaces after the tests clearly showed that surface modification of PI films increased titania layer adhesions. Effect of hydrothermal treatments on film formability and adhesion strength between titania-PI film interfaces was also evaluated.     

Anti-Reflective Coatings for CRTs by Sol-Gel Process

Two types of anti-reflective coatings composed of nano-particles were developed for cathode ray tubes (CRTs). The anti-reflective and anti-static coating is composed of two layers. An outer SiO₂ layer is formed over a porous inner layer composed of titanium oxynitride (TiO _x N_y), antimony-doped tin oxide (ATO) and SiO₂. To control the reflection of the film, a porous structure is formed using a mixed sol composed of TiO _x N _y -ATO particles and hydrolyzed-polymerized tetraethoxy-silane (TEOS). The resulting double layered coating is shown to consist in a nanocomposite pseudo three-layer structure. The antireflective electromagnetic-wave-shielding coating is also composed of two layers. An outer SiO₂ layer is formed over an electric-conductive inner layer composed of silver colloids, TiO _x N _y nano particles. Silver colloids are used to obtain a film having low surface resistivity and TiO _x N _y nano-particles contained in the inner layer enhance the durability of the film. To reduce the plasma-resonance absorption caused by silver colloids, silver ions are added to the outer layer solution. The silver ions diffuse into the inner layer from the outer layer when the film is cured, touch to the surface of silver colloids, suppress the silver colloid growth and reduce the specific absorption of the film. These coatings are successfully applied to the panel glass for CRTs on an industrial scale.     

SiO2/TiH2包覆粉体的制备及其释氢特性

熔体发泡法因可通过其简单的工艺制备高强度的泡沫铝而受到广泛的关注．TiH2颗粒可以作为泡沫铝的发泡剂，但其仍存在分解温度与铝熔点的温度失配问题．这种温度失配是导致泡沫铝制品孔洞结构难以控制的最大障碍，解决办法之一是延迟TiH2的分解过程．     

Investigation of interface,microstructure, and mechanical properties of layered thermal barrier coatings of lanthanum zirconate and YSZ deposited by EB‐PVD process

Microstructure of the double‐layered ceramic thermal barrier coatings of lanthanum zirconate (LZ) and yttria‐stabilized zirconia (YSZ) with bond coat on Ni‐based superalloy deposited by electron beam evaporation process has been studied. Two sets of combination of LZ and YSZ were deposited: one LZ over YSZ and the other YSZ over LZ. The interfaces of each layer were studied and were found to be sharp; however, some diffusion of elements from below layer was observed. The detailed selected area diffraction of the phases was carried out from the coating cross‐section specimens. The LZ layer was mostly found to be amorphous, and fine columnar growth was observed. The YSZ layer over LZ showed two different crystal structures at interface and at the top surface, which were cubic and tetragonal, respectively. The YSZ layers showed clear columnar grains with feather‐like intercalated structure Copyright © 2014 John Wiley & Sons, Ltd.     

Features of the occurrence of electrochemical processes in contact of sodium chloride solutions with the surface of superhydrophobic coatings on titanium

A joint analysis of the results of electrochemical studies and the evolution of the parameters of a sodium chloride solution droplet in contact with the coating under test reveals the pattern of changes in the surface state which result from the electrochemical reactions and adsorption-desorption processes at the coating/electrolyte interface. Features of the corrosion process are studied on titanium samples with different protective layers on the surface: (1) a natural oxide, (2) a coating prepared via plasma electrolytic oxidation (PEO coating), (3) a PEO coating with a hydrophobic layer, and (4) a PEO coating with a superhydrophobic nanocomposite layer. The best protective properties in a chloride-containing electrolyte are exhibited by the superhydrophobic nanocomposite coating. The mechanism of corrosion protection of this coating is formulated.     

Mechanisms behind concentration profiles illustrated by charge and concentration distributions around ions in double layers

The mechanisms behind the behaviour of concentration and charge density profiles in diffuse electric double layers are investigated quantitatively for 1:1 and 2:2 electrolytes. This is done by analysing various contributions to the mean force that acts on each ion. The forces are obtained from the calculated ionic charge and concentration distributions around individual ions at various positions in the double layer. These distributions are presented graphically which allows an immediate visual illustration of the mechanisms in action. Some features studied are charge inversion in double layers for divalent aqueous electrolytes, overcompensation of surface charge due to large amounts of physisorbed counterions, ion size effects in the double layer structure and various mechanisms that cause deviations from the predictions of the Poisson–Boltzmann approximation. A major objective of the paper is to present the results in a visual form and explain aspects of modern double layer theory in a simple manner.     

Comparative Analysis of a Solar Control Coating on Glass by AES, EPMA, SNMS and SIMS

 A solar control coating was analysed by different methods of surface analysis with respect to the layer sequence and the composition and thickness of each sublayer. The methods used for depth profiling were Auger electron spectroscopy, electron probe microanalysis, secondary neutral mass spectroscopy and secondary ion mass spectroscopy based on MCs⁺. The structure of the coating was unknown at first. All methods found a system of two metallic Ag layers, embedded between dielectric SnO_X layers. Additionally, thin Ni-Cr layers of 1–2 nm were detected on top of the Ag layers. Thus the detected layer sequence is SnO_X/Ni-Cr/Ag/SnO_X/Ni-Cr/Ag/SnO_X/glass. The Ni:Cr ratio in the nm-thin layers could be quantified by every method, the Cr fraction corresponding to less than one monolayer. We compare the capabilities and limitations of each method in routinely investigating this solar control coating. Importance was attached to an effective investigation. Nevertheless, by combining all methods, measuring artefacts could be uncovered and a comprehensive characterisation of the system was obtained.