循环伏安法对自组装分子沉积膜屏蔽效应的研究

用循环伏安法研究了分子沉积（ＭＤ）膜的屏蔽效应，讨论了不同条件对其成膜性和稳定性的影响，得到了金电极表面沉积规整ＭＤ膜的一般机制和佳成膜条件，证实了ＭＤ膜的自发有序排列的组装过程。     

声发射和激光拉曼研究镍氧化机制中的稀土元素效应

对纯镍及其表面离子注钇样品在1000℃空气中的恒温氧化和循环氧化行为进行了研究。用扫描电镜(SEM)和透射电镜(TEM)对氧化膜的表面形貌及结构进行了观测。研究表明离子注钇极大地提高了金属镍的抗氧化性能。此外,用声发射(AE)技术研究了氧化膜／基体界面上缺陷的分布情况,并用激光拉曼(Raman)谱对注钇引起的膜内应力变化进行了测量。结果表明,离子注钇降低了NiO氧化膜的生长速率,减小了表面NiO的晶粒尺寸,降低了膜内压应力水平。同时,离子注钇还减小了氧化膜／基体界面缺陷的平均尺寸和数目,因此,极大地提高了镍表面NiO氧化膜的粘附性和保护性。     

电化学石英晶体微天平研究六氟亚铁铜膜修饰电极及其离子效应

利用电化学石英晶体微天平（ＥＱＣＭ）手段，结合循环伏安法，计量电流法对六氰亚铁铜（ＣｕＨＣＦ）膜修饰电极及其在不同水溶液中的离子交换机制进行了研究。结果表明：通过循环伏安法，在Ｐｔ电极上可以牢固地形成ＣｕＨＣＦ膜。在氧化还原过程中，不仅是阳离子，阴离子也参与了在ＣｕＨＣＦ膜中的传输     

掺杂靛红的聚吡咯膜的电色效应

制备了掺杂靛红的聚吡咯（ＰＰｙ）膜修饰电极，这种功能化ＰＰｙ膜电极具有很好的电色效应，其颜色变化明显，响应时间短，稳定性好，是一种新型电色材料。     

Marangoni效应与液膜振荡*

本文系统地总结了Marangoni效应的形成、发展及其与液膜振荡现象的关系,用Marangoni效应定量分析讨论了3种不同的液膜振荡体系,给出了有关数学公式,并与液膜振荡的化学本质学说作了对比。     

甲烷水合物分解及自保护效应的分子动力学模拟

采用分子动力学(MD)方法, 在温度T = 240, 260, 280和300 K的条件下模拟了Ⅰ型甲烷水合物晶体的分解过程. 研究发现,水合物分解后将在相界面上形成一层“准液膜”,准液膜中水分子的结构性质、空间取向和动力学性质均出现由“似晶”到“似液”的渐变过程. 在水合物分解过程中, 准液膜的存在对水分子和甲烷分子的扩散形成传质阻力. 由于甲烷分子必须穿过准液膜才能进入气相, 准液膜的传质阻力抑制了甲烷分子向气相的扩散过程, 致使水合物的分解速率随之降低, 从而产生自保护效应. 当温度低于水的冰点时, 准液膜中水分子的“似晶”程度较高, 准液膜的传质阻力较大, 自保护效应较明显. 当温度高于水的冰点时, 准液膜中水分子的“似液”程度较高, 准液膜的传质阻力显著下降, 水合物的自保护效应明显减弱.     

电化学石英晶体微天平研究六氰亚铁铜膜修饰电极及其离子效应

利用电化学石英晶体微天平（EQCM）手段，结合循环伏安法．计时电流法对六氰亚铁铜（CuHCF)膜修饰电极及其在不同水溶液中的离子交换机制进行了研究。结果表明；通过循环伏安法，在Pt电极上可以牢固地形成CuHCF膜．在氧化还原过程中，不仅是阳离子，阴离子也参与了在CuHCF膜中的传输。     

电化学方法对两性接枝星形聚合物LB膜屏蔽效应的研究

本文将自制Y式玻碳电极拉上两性接枝星形聚合物(GPSMA)的LB膜,用循环伏安法研究谈膜的屏蔽效应,讨论了接枝量、成膜条件等对膜缺陷的影响,并提出了减少缺陷的办法。     

紫外光固化PDLC膜性能的温度效应

考察了紫外光固化PDLC膜的电光性能及其温度依赖性,阐述了其作为显示器件的工作稳定性。指出确定PDLC工作温度范围的方法,对PDLC膜中液晶相的N-I转变行为及其与膜的内部结构的关系进行了讨论。     

稀土掺杂硅铝氧烷凝胶的制备及电流变效应

采用乳液聚合的方法以α－甲基丙烯酸甲酯为单体对硅铝氧烷溶胶进行表面覆合，将所制得包裹了PMMA的高介电硅铝氧烷凝胶粉末，与硅油相充分混合是到了电流变效应非常显著的ER流体。同时，通过掺杂稀土化合物得到了一系列掺杂了稀土离子的PMMA包裹的硅铝氧烷凝胶粉末样品，测量 了在外加电场作用下该ER流体粘度随不同的样品浓度，不同的掺杂离子，温度的改变等影响，同时测量了漏电流密度，介电常等相关的物理量。讨论了乳液聚合原理，电流变效应机制。     

Characterization of the PPO dense membrane prepared at different temperatures by ESR,atomic force microscope and gas permeation

Dense (homogeneous) membranes were prepared from poly(2,6-dimethyl-1,4-phenylene oxide) (PPO) by using 1,1,2-trichloroethylene as a solvent at different solvent evaporation temperatures (22,4 and −10°C). The effect of temperature used during evaporation of solvent on the characteristics of the membrane was studied by using electron spin resonance, atomic force microscopy and gas permeation rate. The morphology of the surfaces of the membrane, the shape of spin probe in the membrane, and the selectivity of gases depend on the temperature of evaporation of solvent. The permeation rate of CO₂ increased with the decrease in the temperature used for the preparation of the membrane. However methane permeation rate increased in the membrane prepared at −10°C. It is suggested that Langmuir sites could be favorable for the CH₄ permeation.     

Steady-state distribution of water in cellulose acetate membrane

The effect of hydrostatic pressure applied to a solution on one side of a membrane on the steady-state concentration distribution of permeating solvent inside the membrane has been examined with a view to distinguishing between different mechanisms of permeation in reverse osmosis. The concentration gradients found experimentally in stacks of cellulose acetate films support the view that permeation takes place by diffusion in a nonporous membrane.     

Solvent-induced morphological change of microporous hollow fiber membranes

Microporous polyethylene hollow fiber membranes (EHF-1 and EHF-2) were subjected to solvent treatment, and the effects of this treatment on membrane morphology and permeating properties were studied. Membranes treated with various organic solvents exhibited enhanced permeability, enlarged pore size, and increased shrinkage in the longitudinal direction. These phenomena were found to depend on the surface tension of the solvent: the higher the surface tension of the solvent, the larger the change in morphology and permeation of the membrane. A mechanism to account for the effects of solvent treatment on the morphology of the membrane is proposed taking into consideration the influence of the type of solvent used for treatment. The enhanced morphological and permeation changes are ascribed to the formation of liquid bridges between two microfibrils of the membrane during drying followed by the deformation and adhesion of the adjacent microfibrils based on the surface tension of the solvent.     

Effect of poly(ethylene glycol) 200 on the formation of a polyetherimide asymmetric membrane and its performance in aqueous solvent mixture permeation

To investigate the effect of poly(ethylene glycol) (PEG) 200 on membrane performance, asymmetric polyetherimide (PEI) membranes with a small pore size were prepared by dry/wet-phase inversion from the casting solution containing N-methyl-2-pyrrolidone as a solvent and poly(ethylene glycol) 200 as an additive. Our experiment revealed that the addition of PEG 200 has an influence on the casting solution properties, permeation properties, and resulting membrane structures. Moreover, a drying process also affects the formation of a dense skin layer. Increasing the amount of PEG 200 drastically improved the solute rejection rate. The drying process improved the rejection rate. We also observed the effect of the mixed solvent (water/ethanol) on permeation through the membranes with various pore sizes. In the case of the membrane with a dense skin layer, the solvent permeation showed relationships with solution viscosity, surface tension, and membrane-solvent interaction.     

Permeation of electrolyte water-methanol solutions through a Nafion membrane

The volume flux through a cation-exchange membrane (Nafion 117) separating two equal electrolyte water-methanol solutions as a function of the pressure difference was determined under different experimental conditions. The results show that permeation rates through the membrane are strongly dependent on the methanol content of the solutions, thus the value of the flux increases when the methanol percentage increases. The effect of the electrolyte concentration of the solution on the membrane permeability is less important, although its influence becomes significant at low electrolyte concentration and high methanol content on solvent. This behavior is explained in terms of the amount of solvent sorbed by the membrane. Typical flux behaviors observed with pressure difference are linear at low pressures, exhibiting a positive deviation at higher pressure difference values.     

Driving force for hydraulic and pervaporative transport in homogeneous membranes

Experiments were designed to demonstrate that the chemical potential gradient required for liquid transport through swollen network polymer membranes manifests itself as a concentration gradient and that the rate of transport is independent of how this gradient is established. The fluxes of various liquids through a crosslinked rubber membrane were measured in hydraulic and pervaporation modes of permeation. The pressure applied downstream in the latter act simply to fix the activity of the liquid in the downstream membrane surface. The experiments show the flux is a unique function of this activity, and it does not matter how it is established. Sorption data were used to convert these results into a plot of flux versus concentration differential across the membrane which was analyzed by Fick's law using a model for the concentration dependence of the diffusion coefficient. Measured ceiling fluxes for pervaporation for a number of liquids were found to be the same as those estimated from hydraulic permeation data. A simple mathematical representation for an ideal system is used as a pedagogical device to demonstrate the conclusions.     

Forces due to capillary-condensed liquids: Limits of calculations from thermodynamics

Bridges of capillary-condensed liquid can produce strong adhesion between particles in a vapor atmosphere. An undersaturated liquid solute may also condense between contacting particles in suspension in the solvent, with dramatic effects on the rate of aggregation of the suspension. The force due to a bridge of capillary condensate can be calculated from macroscopic thermodynamics, but the bridges are often so small that macroscopic thermodynamics may not be applicable. This brief review summarizes recent experiments relevant to the range of applicability of macroscopic thermodynamics to microscopic menisci, both for simple organic liquids and for the important case of water.     

The accumulation of phytoalexin in cucumber plant after stress

During the course of pathogens penetrating the plant cell, besides of chemical secretion, the pathogens may cause mechanical signal by the physical pressure on the plant cell. In the current study, we use the pressure as the stress signal to study the induction in plant resistance and the effect of accumulation of phytoalexin. We found that stress can induce the resistance in cucumber seeding significantly. Peptides contained RGD motif can specific block the adhesion between plant cell wall and plasma membrane. When breaking the plant cell wall and plasma membrane by using RGD peptides, the stress induction effect is almost absolutely eliminated. The results of assay with TLC and HPLC showed that stress stimulation could increase the accumulation of cucumber seeding phytoalexin. So, we can conclude that the accumulation of phytoalexin is one possible reason of improve the stress induced resistance. When block the adhesion between plant cell wall and plasma membrane by RGD, there are only part of accumulation of phytoalexin. The results suggest that stress induced resistance and accumulation of phytoalexin of plant is required for the adhesion of plant cell wall–plasma membrane.     

Selective separation of aromatic hydrocarbons through supported liquid membranes based on ionic liquids

Ionic liquids are emerging as alternative solvents for volatile organic compounds traditionally used in liquid–liquid extraction and liquid membrane separation. In this paper, we examine whether room-temperature ionic liquids as a membrane solution can be utilized for hydrocarbon separation by using a supported liquid membrane. Aromatic hydrocarbons, benzene, toluene and p-xylene were successfully transported through the membrane based on the ionic liquids. Although the permeation rates through the membrane based on the ionic liquids were less than those of water, the selectivity of aromatic hydrocarbons was greatly improved. The maximum selectivity to heptane was obtained using benzene in the aromatic permeation and 1-n-butyl-3-methylimidazolium hexafluorophosphate in the liquid membrane phase.     

Effects of the relative humidity and water droplet on adhesion of a bio-inspired nano-film

Inspired by geckos' adhesion, the effect of water membrane forming due to the environmental humidity, on the adhesion between a bio-inspired nano-film and a substrate is investigated first. The disjoining pressure is considered, which results in an enhancing adhesion between the nano-film and substrate. When the thickness of water membrane increases, water droplets will form and a repulsive capillary force between the nano-film and substrate is produced. The total adhesion force decreases with an increasing volume of water droplets. The two opposite results in the two different models are consistent well with two seemingly inconsistent experimental observations by Huber et al. (2005) [4] and Sun et al. (2005) [5], respectively, and may be significant for the development of artificial biomimetic attachment systems.