PEMFC阴极中氧扩散和电化学反应模型研究—I．TFFA模型及其数值计算

将薄膜浸渍聚集体（TFFA）模型用于描述质子交换膜燃料电池（PEMFC）阴极中氧的扩散和反应过程，其中包括氧气在气体扩散层和反应层气体通道中的扩散，氧气在反应层薄膜中的溶解和扩散，氧在反应层浸渍聚休体中的扩散和反应以及电子和离子的传导，并根据PEMFC阴极的结构特点给出TFFA模型的数值解法。     

PEMFC阴极中氧扩散和电化学反应模型研究Ⅱ. TFFA模型参数对电极性能的影响

运用薄膜浸渍聚集体（TFFA）模型，考察了质子交换膜燃料电池（PEMFC）阴极伏安曲线受阴极结构参数变化的影响程度。计算结果表明：阴极反应层的孔隙率和厚度、反应层中浸渍聚集体体积分数、半径和涂覆的薄膜厚度、Nafion电解质离子传导率以及气体扩散层的平均孔径对电极性能有较大的影响。相比之下，反应层中气体通道半径、气体扩散层孔隙率以及反应层中碳相传导率的变化对电极性能影响不大。     

PEMFC阴极中氧扩散和电化学反应模型研究Ⅰ.TFFA模型及其数值计算

将薄膜浸渍聚集体(TFFA)模型用于描述质子交换膜燃料电池(PEMFC)阴极中氧的扩散和反应过程,其中包括氧气在气体扩散层和反应层气体通道中的扩散,氧气在反应层薄膜中的溶解和扩散,氧在反应层浸渍聚集体中的扩散和反应以及电子和离子的传导,并根据PEMFC阴极的结构特点给出TFFA模型的数值解法.     

TiO2/十六烷基三甲基溴化铵有序交替层状纳米复合薄膜的制备与结构表征

近年来有序交替的层状纳米结构薄膜的制备吸引了研究者们的极大关注. 目前, 这类薄膜的制备方法研究得最多的是LB技术[1～3]、基于化学吸附的自组装成膜技术[4,5]和交替沉积组装技术[6～8]. 但这几种方法都有明显的缺陷[9,10], 其中,通过LB技术制备有序交替层状纳米复合薄膜需要昂贵的仪器, 而且由于层间是分子相互作用, 膜的稳定性较差; 基于化学吸附的自组装成膜技术由于需要高反应活性的分子和特殊的基底表面, 并且由于化学反应的产率很难达到100%, 因此通过这种方法制备结构有序的多层膜并不容易; 利用交替沉积的方法制备出具有实用厚度的纳米多层膜需要耗费大量的时间. 最近, 出现了一种称为蒸发诱导的超分子自组装方法, 由这种方法制备的纳米多层膜具有成膜速度快和膜有序度高等优点, 此外还可以通过改变成膜物质浓度和拉膜速度来控制薄膜的厚度, 但与LB膜相比其厚度无法在分子水平上控制. 利用这种方法制备多层膜目前的文献报道仅限于线形SiO2与有机物的组装[10～13]. 本文利用这种方法制备了TiO2/十六烷基三甲基溴化铵纳米复合薄膜并对其结构进行了表征, 结果表明所制备的薄膜具有TiO2/十六烷基三甲基溴化铵有序交替的层状结构.     

聚乳酸自支持膜的叠加及其作为药物控释阻隔层的研究

发展了一种将自支持膜层层叠加制备多层膜的新方法,并研究了该薄膜对药物释放的调控效果. 首先利用聚乙烯醇作为牺牲层制备出聚乳酸自支持膜,然后将聚乳酸自支持膜转移或层层叠加到载药薄膜表面,最后对覆盖有聚乳酸薄膜的载药膜进行药物释放研究. 实验结果表明,聚乳酸薄膜对药物的释放起到了明显的调节作用,并且转移的薄膜的控释效果优于原位制备的薄膜,多层叠加的薄膜控释效果强于同等厚度的单层薄膜. 这可能是由于转移和叠加的薄膜层与层之间的空隙对药物的释放起到了缓冲作用所致. 这种基于自支持膜叠加制备多层膜的方法为药物涂层的研究提供了新思路,在生物材料、医用植入器件等领域都有一定的发展前景.     

层间反应法制备CaGa2S4∶Ce电致发光器件

报道了用层间反应法制备ＣａＧａ２Ｓ４∶Ｃｅ薄膜，用电子束蒸发法交替沉积ＣａＳ∶Ｃｅ和Ｇａ２Ｓ３膜，然后经一定的处理，获得ＣａＧａ２Ｓ４∶Ｃｅ膜。Ｘ射线衍射、ＳＴＥＭ显微照片和ＥＤＸ等分析结果表明，产物为结晶度较好、符合ＣａＧａ２Ｓ４∶Ｃｅ化学计量比的发光薄膜，并得到了Ｃｅ３＋的蓝色发光谱。     

钛金属表面结构可控多层钛酸盐纳米管薄膜的制备和结构稳定性

在水热条件下, 通过控制反应温度和氢氧化钠的浓度, 在钛金属表面得到结构可控的多层钛酸盐纳米管薄膜. 根据扫描电子显微镜和高倍透射电子显微镜的观测结果, 认为钛金属表面多层钛酸盐纳米管薄膜的形成经历以下4个阶段: (1) 钛金属的水合和碱性钛酸盐水凝胶的生成; (2) 碱性钛酸盐水凝胶分解并形成层状Na₂Ti₃O₇; (3) 层状Na₂Ti₃O₇的生长; (4) 层状Na₂Ti₃O₇的劈裂和多层卷曲成轴形成纳米管. 研究了薄膜形成后机械处理对薄膜形貌和结构稳定性的影响, 并利用超声的方法实现了多层膜的层分离.     

层间反应法制备CaGa2S4：Ce电致发光器件

报道了用层间反应法制备了ＣａＧａ２Ｓ４：Ｃｅ薄膜，用电子束蒸发交替沉积ＣａＳ：Ｃｅ和Ｇａ２Ｓ３膜，然后经一定处理，获得了ＣａＧａ２Ｓ４；Ｃｅ膜。Ｘ射线衍射，ＳＴＥＭ显微归照片ＥＤＸ等分析结果表明，产物为结晶度较好，符合ＣａＧａ２Ｓ４；Ｃｅ化学计量比的发光薄膜，并得到了Ｃｅ＾３＋的蓝色发光谱。     

二维多层PtRu/PtNd纳米薄膜的结构效应及电催化氧化活性

采用离子束多靶溅射技术控制膜层结构制备出二维多层PtRu/PtNd纳米合金薄膜作为微型直接甲醇燃料电池(DMFCs)阳极催化电极材料. 应用X射线光电子能谱(XPS)、原子力显微镜(AFM)、X射线衍射(XRD)、掠入射X射线衍射(GIXD)研究了薄膜表面的化学状态、形貌以及薄膜表层、次表层和体相的结构,并用CO-stripping伏安法、循环伏安法(CV)、线性扫描伏安法(LSV)、计时电流法(CA)等电化学方法测试薄膜催化剂的电化学活性比表面积及其对甲醇的电催化氧化. 结果表明, 多次交替沉积制备的PtRu/PtNd薄膜, 由于溅射产生的Pt+、Ru+和Pt+、Nd+之间的相互作用, 使薄膜表面的化学状态和膜层结构发生变化, 其衍射谱峰呈现异常宽化, Pt与Nd之间产生电子转移, 证实了PtRu/PtNd纳米合金薄膜是一种具有特殊膜层结构和电子结构的二维多层PtRu/PtNd纳米合金薄膜, 电化学活性比表面积高达115.00m2 ·g-1, 在酸性溶液中电催化氧化甲醇的活性显著提高.     

二氧化钛超薄膜的组装

近年来LB膜技术和超微粒子研究的发展，将两者有效地结合起来组装了与量子电子学、非线性光学、光电化学、化学生物传感器有关的纳米量级无机半导体材料［‘－‘j．其中TIO。纳米薄膜材料已在太阳能电池反射膜、压电铁电薄膜、电致显示器件［‘j、可逆光电池和超导薄膜［’］研究中都显示了广阔的应用前景．这类薄膜制备多采用化学气相沉积（CVD）技术和原子层外延．也有人把LB技术应用于纳米粒子的组装来制备TIO。超薄膜［”’j二本文利用烷氧基钛在水／空气界面上发生的溶胶一凝胶化反应制备TIO。基胶态粒子及其固态凝聚膜，将其与…     

Reflection–absorption infrared spectroscopy investigation of the crystallization kinetics of poly(ethylene terephthalate) ultrathin films

Reflection–absorption infrared spectroscopy was used to study the crystallization behavior of poly(ethylene terephthalate) (PET) ultrathin films. The crystallinity of ultrathin films was estimated by the fraction of trans conformers of PET. The isothermal and nonisothermal crystallization kinetics of ultrathin films with different thicknesses were investigated. The thinner PET film showed slower kinetics during isothermal crystallization than the thicker film. Moreover, the final crystallinity of films with various thicknesses were reduced with decreasing thickness. An Avrami equation was used to fit the acquired results. The Avrami exponents decreased with the film thickness. As for the nonisothermal crystallization, the cold‐crystallization starting temperature shifted to a lower temperature as the film thickness increased. The influence of the substrate on the crystallization kinetics of the films was also studied. The half‐crystallization times and final crystallinities of ultrathin films adsorbed onto a self‐assembled‐monolayer‐treated surface and an untreated substrate were clearly different, although their thickness dependence was similar. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 4440–4447, 2004     

Role of the Confined Geometry on the Crystallization of Poly（ethylene terephthlate） Ultrathin Films

The reflection-absorption infrared (RAIR) was employed to study the crystallization kinetic of poly (ethylene terephthalate) (PET) ultrathin films. During isothermal crystallization the thinner PET film shows a slower kinetic compared with the thicker film. Moreover, the final crystallinity of films with various thickness was found decrease with thickness. The result of fitting our data to Avrami equation showed that the Avrami exponents decrease with film thickness.     

Quick pH-responsive Films Prepared from Urethane Acrylate Anionomers Under UV Radiation and Their Responsive Performances

Urethane acrylate anionomers(UAA) were prepared in various compositions by three steps. Under UV radiation, UAA formed pH-sensitive films with drying film thicknesses of 60,200 and 330 ttm. The equilibrium swelling ratios(SR) of the films in various pH buffer solutions increased with the increase of the molecule weight of UAA. The influence of the film thicknesses on the swelling performances of the films was investigated. The film with a thickness of 60μm could reach the equilibrium state in 2.5--3.5 min. A high SR was obtained for a thick film due to its low average network density. The cured film could swell reversibly and rapidly with the change of pH, which is important for a controlled release system.     

Plasma Polymerization on Metals

An ellipsometric technique is described for accurately measuring the film thickness of plasma-polymerized polymers on metallic substrates. The index of refraction n and absorption index Kof the plasma polymer film can also be studied by ellipsometry. Films of plasma polystyrene and polyepichlorohydrin were deposited on evaporated aluminum substrates and their thickness and optical constants determined. Plasma polystyrene films from 20 to 1600 Å thick have optical constants n = 1.63 and K =0 independent of film thickness. Plasma polyepichlorohydrin films over the same range of thickness give n ? 1.70 and K? 0.01. By utilizing the ellipsometric method the effect of plasma polymer film thickness on surface energy properties was determined. Advancing contact angle measurements and surface energy analysis detail the polar γSV^P dispersion γSV^Pcontributions to the solid-vapor surface tension γSV = γSV^d + γSV^P Polystyrene and polyepichlorohydrin films on etched aluminum. For thin plasma polystyrene films (600 Å), anomalies in the calculated surface energy are discussed and related to possible surface nonuniformity caused by film growth. Thicker films of plasma polystyrene are shown to have normal surface energy properties as does plasma poly-epichlorohydrin over the entire range of film thickness measured. The adhesive and cohesive properties of plasma polystyrene and polyepichlorohydrin films are discussed as estimated from a lap-shear bond strength study. Etched aluminum coated with various thicknesses of these two polymers and bonded with an epoxy-phenolic adhesive shows a decreasing shear strength with increasing plasma film thickness but begins to level off at ～1600 psi for films >1600 Å thick.     

AFM characterization of spin-coated multilayered dry lipid films prepared from aqueous vesicle suspensions

We present a detailed AFM study on multilayered dry lipid films prepared from aqueous vesicle suspensions. Different preparation techniques were applied in order to optimize the preparation of homogeneous lipid films of various film thicknesses. Suspensions of preformed DOPC/DPPC vesicles were adsorbed onto indium tin oxide-coated glass coverslips, a substrate also commonly employed for the formation of giant liposomes. We found that the homogeneity of the lipid films could substantially be improved when applying a spin-coating step during the film preparation. These films were much more homogeneous than those prepared by conventional drop-casting and in addition the film thickness could be controlled. When using a combination of vesicle adsorption and spin-coating the quality and thickness of the films depended crucially on the lipid concentration of the vesicle suspension, the adsorption temperature and the adsorption time. For lipid films prepared by direct spin-coating the lipid concentration and the applied spin-coating sequence were critical parameters for the quality and thickness of the deposited lipid films.     

金属铝诱导法低温制备多晶硅薄膜

以氢气稀释的硅烷(SiH₄)和硼烷(B₂H₆)为气源,利用等离子体增强化学气相沉积法(PECVD)制备出p型a-Si薄膜.采用铝诱导晶化技术对不同厚度的铝膜对a-Si薄膜晶化的影响进行了研究.实验中发现,铝膜溅射为10 s的非晶硅薄膜样品在450℃下退火10 min后,p型a-Si结构仍为非晶态,铝膜溅射为20 s的非晶硅薄膜在450℃下退火20 min后,p型a-Si薄膜开始晶化为poly-Si薄膜,并且铝膜厚度越厚,则a-Si薄膜晶化程度越强.     

Thickness dependence of the structural,mechanical and electrical properties of Ni films deposited on polyimide by ion beam‐assisted deposition (IBAD)

Ni thin films with different thicknesses were deposited on pre‐treated polyimide substrates by ion beam‐assisted deposition. Dependence of structural, mechanical and electrical properties of the Ni films on their thickness was investigated. The results showed a clear correlation between film properties and film thickness. The inter‐diffusion at the interface regions of the films with different deposition time were demonstrated by transmission electron microscopy and X‐ray photoelectron spectroscopy. With increasing film thickness, surface roughness of the Ni films firstly decreased and then increased, while the grain size gradually increased. Residual stress of the Ni thin films decreased with increasing Ni film thickness up to 202 nm and then slightly increased as the film thickness further increased. Resistivity decreased, and temperature coefficient of resistivity (TCR) increased with increasing film thickness due to the enhancement of crystallization degree and the increase in grain size. The decrease in surface roughness and residual stress also contributed to the decrease of resistivity and the increase of TCR of the films. An optimal film thickness is suggested, which yielded a relatively high TCR value and low levels of both surface roughness and residual stress. Copyright © 2012 John Wiley & Sons, Ltd.     

Effect of Molecular Weight on Packing during Latex Film Formation

A UV-visible technique is used to study the evolution of transparency during film formation from latex particles. Latex particles with high and low molecular weight (HM and LM) polymethyl methacrylate (PMMA) are used to prepare films. Two sets of films with different latex content were prepared from HM and LM particles separately, by annealing PMMA particles above the glass transition temperature. Transmitted photon intensity, I(tr), from HM and LM films increased as the annealing temperature was increased. The increase in the transmitted photon intensity is attributed to the latex content (film thickness) for the annealed film samples. It is suggested that as the latex particles are packed (film thickness is increased) fewer voids or cracks are formed in the films. Positive and negative absorption coefficients are measured below and above 210 and 180 degrees C annealing temperatures for the HM and LM films. Packing coefficients are obtained for films in various latex contents. It is observed that LM particles are packed much easier than HM particles. Copyright 2001 Academic Press.     

Characteristics of polyelectrolyte multilayers: effect of PEI anchoring layer and posttreatment after deposition

The influence of a first (anchoring) layer and film treatment on the structure and properties of polyelectrolyte multilayer (PEM) films obtained from polyallylamine hydrochloride (PAH) and polysodium 4-styrenesulfonate (PSS) was studied. Branched polyethyleneimine (PEI) was used as an anchoring layer. The film thickness was measured by ellipsometry. Complementary X-ray reflectometry and AFM experiments were performed to study the change in the interfacial roughness. We found that the thickness of the PEM films increased linearly with the number of layers and depended on the presence of an anchoring PEI layer. Thicker films were obtained for multilayers having PEI as the first layer comparing to films having the same number of layers but consisting of PAH/PSS only. We investigated the wettability of PEM surfaces using direct image analysis of the shape of sessile water drops. Periodic oscillations in contact angle were observed. PAH-terminated films were more hydrophobic than films with PSS as the outermost layer. The effect of long time conditioning of PEM films in solutions of various pH's or salt (NaCl) concentrations was also examined. Salt or base solutions induced modification in wetting properties of the polyelectrolyte multilayers but had a negligible effect on the film thickness.     

智能响应与自修复的层层组装聚合物膜

具有刺激响应性和自修复功能的复合膜是重要的仿生功能膜材料.层层组装是一种基于物质交替沉积而制备复合膜的方法,可以实现膜的结构和组成的精确调控.通过结构与组成的精确调控,基于层层组装制备的微米厚度的聚电解质厚膜可以对外界刺激产生快速有效的响应,因而在制备智能仿生膜材料方面具有重要的价值.本文以作者的研究结果为基础,阐明了基于层层组装的聚电解质膜可以成功用于制备湿度和温度响应的双结构自支持膜和高效的促动器及行走机器,以及自修复超疏水和划痕修复聚电解质膜.