测定潮湿空气中粒子所含硫酸和硝酸根离子的方法

对复合薄膜法进行了改进，将人工粒子通过干燥器去除水蒸汽的不利影响，采集在镀有硝酸灵（Ｎｉｔｒｏｎ，Ｃ２０Ｈ１６Ｎ４）的膜片上。用真空镀膜法镀上氯化钡薄膜。用该法采集了高湿度下的大气粒子，对硫酸根和硝酸根两类粒子在透射电镜中进行观察，根据生成物的形态，测定出潮湿空气中粒子所含的酸性离子。     

均一沉淀法云母片被覆TiO2

利用硫酸氧钛和的均一沉淀反应法，在天然矿物云母上被覆ＴｉＯ２薄膜，讨论了薄膜形成主影响膜层结构的工艺因素，分阶段控制反应温度和时间有利于控制析出粒子形态和膜最，可获得均匀致密切的膜，不同厚度的膜层因光学干涉效应显示出各种色彩。     

六苯基硅烷-聚乙烯醇荧光复合薄膜的制备及传感性能

以聚乙烯醇(PVA) 高分子凝胶薄膜为基质, 将有机小分子发光染料六苯基硅烷(HPS) 纳米粒子掺杂到PVA薄膜内, 利用HPS的聚集诱导发射效应和凝胶薄膜的基质效应制备得到一种新型荧光薄膜. 扫描电子显微镜观察发现该薄膜具有典型的三维网络结构; 静态荧光光谱监测表明, 薄膜荧光性能稳定, 且荧光发射来自于无定形态和结晶态的HPS纳米粒子, 其中无定形态发射居多; 传感实验表明, 该薄膜对芳香族化合物气体表现出了灵敏的传感性, 灵敏度和猝灭效率取决于有机溶剂的挥发速度和薄膜的表面结构; 结合荧光寿命测定结果和HPS纳米粒子的发光机理, 推测芳香族化合物对薄膜荧光的猝灭源自其对HPS聚集体的解聚集作用; 实验还表明, 该薄膜对此类气体的传感呈现出良好的可逆性.     

水/油界面上自组装金纳米粒子单层薄膜

采用界面自组装的方法制备了金纳米粒子单层薄膜。该方法克服了传统制备金纳米粒子薄膜需要引入第三种助剂的缺点,仅用金溶胶和另外一种疏水溶剂通过简单的混合,就可得到金纳米粒子单层薄膜。通过调节疏水溶剂的极性,可以调节组成金膜中金纳米粒子的数密度,即纳米粒子的间距。     

气-液界面Au纳米粒子网状结构薄膜的制备及SERS性能研究

本研究通过自组装法在气-液界面得到Au纳米粒子网状结构,并通过进一步生长得到连续的Au纳米粒子网状结构薄膜.该方法无需加入任何诱导剂,在室温条件下即可得到稳定性良好的纳米金薄膜.通过改变HAuCl_4和AgNO_3相对用量、陈化时间等条件对网状结构薄膜的形成机理进行了研究.结果发现,AgNO_3用量对Au纳米粒子薄膜的形成至关重要,通过调控AgNO_3用量可以促进纳米金粒子间的融合并形成纳米链、进一步演化为纳米链网状结构.在初步形成的Au纳米粒子网状结构表面通过抗坏血酸还原进一步生长纳米金粒子,有利于形成较大面积、较好稳定性的纳米Au粒子网状结构薄膜.以对氨基苯硫酚(4-ATP)作为探针分子,研究表明,与未发生组装的金纳米粒子相比,自组装形成的Au纳米粒子网状结构薄膜对4-ATP具有较强的表面增强拉曼效应.     

二氧化硅纳米粒子薄膜的制备及光学性能

以二氧化硅胶体和聚二烯丙基二甲基氯化铵(PDDA)为原料,利用静电自组装技术制备了PDDA/SiO2复合薄膜. TEM图象显示,薄膜中的SiO2纳米粒子为密堆积,薄膜均匀、致密;电子衍射实验结果显示,所组装的薄膜为非晶态膜.载玻片表面组装SiO2纳米粒子薄膜后,透射率随薄膜双层数增加呈现周期变化.薄膜具有增透作用,载玻片双面组装薄膜后在一定波长范围内的透射率可提高5％以上. PDDA/SiO2复合薄膜的光学性质主要由SiO2纳米粒子决定,每一双层的平均物理厚度小于SiO2纳米粒子的粒径,薄膜中存在层间穿插现象,逐层组装的复合薄膜具有单层光学薄膜的特性.     

硫醇类配体修饰金纳米粒子在嵌段共聚物中自组装的研究进展

本文综述了不同类型硫醇配体修饰金纳米粒子的合成方法以及功能性金纳米粒子在嵌段共聚物薄膜中的自组装研究进展,重点介绍了硫醇类配体修饰金纳米粒子的合成方法,包括Brust合成法、原位合成法、grafting from合成法、配体置换法、单晶模板法等。总结了硫醇基小分子或聚合物配体修饰的金纳米粒子与嵌段共聚物之间自组装的调控方法,如利用配体与嵌段共聚物组分的隔离作用、配体与嵌段共聚物组分形成的氢键作用、溶剂蒸气退火或热退火等诱导嵌段共聚物/纳米粒子复合薄膜自组装。展望了功能性金纳米粒子以及嵌段共聚物/金纳米复合材料的发展方向。     

氧在Ni-MnO2电极上的电催化还原

采用喷雾热解法合成了超细二氧化锰, 通过喷涂制作成Ni-MnO2薄膜电极, 结合SEM、AFM和电化学测试技术, 研究了碱性介质中氧在Ni-MnO2薄膜电极上的电催化还原过程. 发现二氧化锰颗粒呈片状, 是由球形前驱体烧结后碎裂而成; 通过快速循环伏安法检测到了MnO2电极上存在着中间态粒子的还原过程, 该粒子浓度可累积, 并逐渐消耗直至消失, 寿命可持续约200周循环; 结果表明, 该粒子对氧的还原具有特殊的电催化活性.     

纳米稀土-介质薄膜光电发射光谱和能带结构

用真空蒸发沉积的方法制备了纳米稀土(La、Nd、Sm)粒子 BaO介质薄膜.研究表明薄膜的光电发射光谱响应阈值受纳米稀土粒子形状和大小的影响,球形纳米稀土(Sm)粒子 BaO介质薄膜的光谱响应阈值波长为720 nm,条状纳米稀土(La和Nd)粒子 BaO介质薄膜阈值波长分别为650 nm和660 nm.研究得到纳米稀土粒子 介质薄膜等效界面位垒高度在1.7～2.0 eV之间.由于纳米稀土粒子与BaO介质各自逸出功不同,当构成薄膜后使得纳米粒子周围的空间电荷分布发生变化,纳米粒子周围的能带发生弯曲.     

纳米稀土-介质薄膜光电发射光谱和能带结构

用真空蒸发沉积的方法制备了纳米稀土(La、Nd、Sm)粒子-BaO介质薄膜.研究表明薄膜的光电发射光谱响应阈值受纳米稀土粒子形状和大小的影响,球形纳米稀土(Sm)粒子-BaO介质薄膜的光谱响应阈值波长为720nm,条状纳米稀土(La和Nd)粒子-BaO介质薄膜阈值波长分别为650nm和660nm.研究得到纳米稀土粒子-介质薄膜等效界面位垒高度在1.7～2.0eV之间.由于纳米稀土粒子与BaO介质各自逸出功不同,当构成薄膜后使得纳米粒子周围的空间电荷分布发生变化,纳米粒子周围的能带发生弯曲.     

Optochemical sensing by immobilizing fluorophore-encapsulating liposomes in sol–gel thin films

The chemical stability of optochemical sensors depends largely on the physiochemical properties of the supportive matrix of the sensor and on the method used to immobilize sensing reagents to the supportive matrix of the sensor. Leaking of physically immobilized sensing reagents from the matrix support decreases the stability of the sensor and its overall usefulness. Covalent immobilization eliminates leakage of the sensing reagent from the support but may lead to alteration of spectral properties and loss of analyte response. This paper presents a new method for physical immobilization of polar fluorescence dyes in a sensing support. The method is based on the immobilization of fluorescent dye encapsulating liposomes in a sol–gel film of micrometer thickness. The encapsulation of the dye molecules in the liposomes effectively increases the molecular dimensions of the sensing reagent, thus preventing its leakage from the matrix support. This paper describes the analytical properties of a pH sensor fabricated by immobilizing carboxyfluorescein-encapsulating liposomes in a sol–gel thin film. The sensor shows excellent stability with respect to dye leaking which in turn leads to high reproducibility and sensitivity of about 0.01 pH units. The linear dynamic range of the sensor is between pH 6 and 7.5 and its response time is at the sub-seconds time scale.     

Data processing in on-line laser mass spectrometry of inorganic, organic, or biological airborne particles

A general solution for data processing of large numbers of micrometer- or submicrometer-particle mass spectra in aerosol analysis is described. The method is based on immediate evaluation of bipolar laser desorption ionization mass spectra acquired in an on-line (impact-free) time-of-flight instrument. The goal of the procedure is a characterization of the particle population under investigation in terms of chemical composition of particle classes, particle distributions, size distributions, and time courses, rather than an investigation of each individual particle. After automatic peak analysis of each newly acquired bipolar mass spectrum, the mass spectral information is statistically evaluated by a fuzzy clustering algorithm, providing for an immediate attribution of the particle to predefined particle classes. The particle distributions over these classes can be monitored as a function of time and particle size range. Definition of the particle classes as used for on-line evaluation is performed in an earlier step, either by manual approach, or by selection from a particle class database, or, as in most cases, by fuzzy clustering of a set of particle mass spectra from the population (the aerosol) under investigation. Definition of the particle classes is depending only on the distinguishability of the spectra patterns of different particles. It is not necessary for the clustering approach to fully “understand” the mass spectra. The range of possible applications of the method is therefore very broad. Particles dominated by inorganic components, as typically observed in aerosol chemistry for example, can be investigated the same way as organic particles (e.g., from smoke or automobile exhaust) or even biological particles such as bacteria, yeast, or pollen. The data processing method has been successfully applied in several fields of stationary applications and will be employed in mobile instruments for large scale field studies in atmospheric chemistry, engine combustion research, and the characterization of house dust.     

Direct measurement of hydrophobic particle–bubble interactions in aqueous solutions by atomic force microscopy: Effect of particle hydrophobicity

Direct measurements of the interaction forces between a spherical silica particle and a small air bubble have been conducted in aqueous electrolyte solutions by using an atomic force microscope (AFM). The silica particle was hydrophobized with a silanating reagent, and the interaction forces were measured by using several particles with different surface hydrophobicities. In the measured force curves, a repulsive force was observed at large separation distances as the particle moved towards the bubble. The origin of the repulsive force was attributed to an electrostatic double-layer force because both the particle and bubble were negatively charged. After the repulsive force, an extremely long-range attractive force acted between the surfaces. These results indicate that the intervening thin water film between the particle and bubble rapidly collapsed, resulting in the particle penetrating the bubble.

The instability of the thin water film between the surfaces suggests the existence of an additional attractive force. By comparing the repulsive forces of the obtained force curves with the DLVO theory, the rupture thickness was estimated. The hydrophobicity of the particle did not significantly change the rupture thickness, whereas the pH of the solution is considered to be a critical factor.     

界面聚合法制备复合膜

本文对近年来国内外利用界面聚合法制备超薄复合膜的研究进行了综述。阐述了界面聚合成膜反应的原理,并从反应单体种类的角度进行分类,对目前由界面聚合法制备复合膜的研究现状进行了较详细的介绍和分析;对界面聚合法制备复合膜存在的问题以及研究前景进行了展望。     

Atomistic simulation of the formation of nanoporous silica films via molecular chemical vapor deposition on nonporous substrates

To distinguish thin deposited film characteristics clearly from the influence of substrate morphological properties, the growth mechanism and the macroscale and nanoscale properties of nanoporous SiO(2) films deposited on nonporous silica (SiO(2)) substrates from chemical precursors Si(OH)(4) and TEOS (tetraethoxysilane) via low-pressure chemical vapor deposition are the primary targets of this study. This work employs a kinetic Monte Carlo (KMC) simulation method coupled to the Metropolis Monte Carlo method to relax the strained silica structure. The influence of the deposition temperature (473, 673, and 873 K) on the properties of the SiO(x) layers is addressed via analysis of the film growth rates, density profiles of the deposited thin films, pore size distributions, carbon depth profiles (with respect to TEOS), and voidage analysis for layers of different thicknesses (8-18 nm). A comparison of simulation with experimental results is also carried out.     

GeS2 and GeSe2 PECVD from GeCl4 and Various Chalcogenide Precursors

The plasma enhanced chemical vapor depositions of germanium chalcogenide thin films from germanium tetrachloride, hydrogen sulfide and alkyl chalcogenides were studied to determine the viability of these reagents for thin film deposition. Hydrogen sulfide is a commonly used reagent for this technique and was used to determine optimal reaction conditions for thin film deposition. Germanium tetrachloride, alkylsulfides and alkylselenides were also employed because of their lower potential toxicities and higher availabilities compared to their more typical congeners: germane, hydrogen sulfide and hydrogen selenide in the formation of germanium chalcogenides. Alkylsulfides were found to be unsuitable for the deposition of germanium sulfides, however alkylselenide precursors were used successfully for the deposition of germanium selenides. The relative mass flow rates, reactor pressure, substrate temperature and plasma power density were studied for their effects on germanium chalcogenide deposition. These parameters affected the composition, deposition rate, film quality, and spectroscopic properties of the deposited films.     

Multi-beam single-molecule defocused fluorescence imaging reveals local anisotropic nature of polymer thin films

We developed a method to determine full three-dimensional orientation distribution of individual molecules based on wide-field defocused fluorescence imaging. Excitation efficiencies of out-of-plane oriented molecules were improved dramatically by illuminating molecules with multiple laser beams. Our high throughput approach allowed us to obtain unbiased statistical distributions of orientations of doped molecules in spin-coated polymer thin films. We found thickness- and glass transition temperature-dependent distributions of the molecular orientations which reflect local chain orientations and relaxation in the polymer thin films.     

Site‐Targeted Interfacial Solid‐Phase Chemistry: Surface Functionalization of Organic Monolayers via Chemical Transformations Locally Induced at the Boundary between Two Solids

Effective control of chemistry at interfaces is of fundamental importance for the advancement of methods of surface functionalization and patterning that are at the basis of many scientific and technological applications. A conceptually new type of interfacial chemical transformations has been discovered, confined to the contact surface between two solid materials, which may be induced by exposure to X‐rays, electrons or UV light, or by the application of electrical bias. One of the reacting solids is a removable thin film coating that acts as a reagent/catalyst in the chemical modification of the solid surface on which it is applied. Given the diversity of thin film coatings that may be used as solid reagents/catalysts and the lateral confinement options provided by the use of irradiation masks, conductive AFM probes or stamps, and electron beams in such solid‐phase reactions, this approach is suitable for precise targeting of different desired chemical modifications to predefined surface sites spanning the macro‐ to nanoscale.     

Formation of metallic Ni nanoparticles on titania surfaces by chemical vapor reductive deposition method

Metallic Ni nanoparticles were successfully prepared on the surface of titania thin film substrate by a novel method, named as chemical vapor reductive deposition (CVRD) method. The growth of the nanoparticles was based on the specific adsorption and heterogeneous nucleation on the surface of substrate, not via vapor-phase formation and subsequent sedimentation. The nanoparticle size was found to be well controllable between 10 and 30 nm by the preparation time and vapor pressure of metal complex precursor. ESCA and electron diffraction results clearly demonstrated Ni nanoparticles as metallic. Titania thin film with metallic Ni nanoparticles on its surface showed high efficiency in their photocatalysis of hydrogen evolution from decomposition of ethanol.