气-液界面上十六烷基溴化吡啶水溶液动态表面张力的研究

滴体积法测定了十六烷基溴化吡啶溶液的动态表面张力。考察了浓度、温度对动态表面张力的影响。讨论了十六烷基溴化吡啶分子在气／液界面上的吸附动力学,发现吸附遵从扩散-动力学控制机理．从表观扩散系数计算了吸附能垒,分析了吸附能垒存在的原因。     

双子表面活性剂Dynol-604溶液的动态表面张力研究

通过测定双子表面活性剂Dynol-604的动态表面张力(DST),研究了温度和浓度等对其DST的影响,详细表征了DST随时间的变化过程,计算了动态表面张力的各种参数(t_i,t^*,t_m,R_1/2).结果表明,其表面张力降低迅速,γ_m值也很低.探讨了上述参数的物理意义和变化规律.     

烷基聚葡糖苷溶液的表面吸附平衡与动力学

用吊片法和气泡最大压力法分别测定了烷基聚葡糖苷(APG)C₉.₆G_1.3水溶液的平衡和动态表面张力,研究了APG水溶液表面的吸附平衡、动力学及其影响因素.测得其cmc(临界胶束浓度)为0.032g/L.吸附过程由初始的扩散控制转变到势垒控制,吸附势垒为4～7kJ/mol.温度升高,平衡和动态表面张力均减小,吸附量增加;加入无机盐,平衡和动态表面张力增大,吸附量亦增加;醇类的吸附使动态表面张力下降速率加快,表明APG与醇分子间有协同吸附作用.     

烷基聚葡糖苷溶液的表面吸附平衡的动力学

用吊片法和气泡最大压力法分别测定了烷基聚葡糖苷（APG）C9.6G1.3水溶液的平衡和动态表面张力，研究了APG水溶液表面的吸附平衡、动力学及其影响因素。测得其cmc(临界胶束浓度）为0.032g/L。吸附过程由初始的扩散控制转变到势垒控制，吸附势垒为4－7kJ/mol。温度升高，平衡和动态表面张力均减小，吸附量增加；加入无机盐，平衡和动态表面张力增大，吸附量亦增加；醇类的吸附使动态表面张力下降速度加快，表明APG与醇分子间有协同吸附作用。     

不同结构烷基苯磺酸钠水溶液的泡沫性能及动态表面张力

研究了一系列直链三取代和支链双取代烷基苯磺酸钠水溶液的动态表面张力(DST)和泡沫性能, 考察了分子结构变化对烷基苯磺酸钠水溶液的DST和泡沫性能的影响. 探讨了动态表面张力参数(t*, n, R1/2)的变化规律及其与泡沫性能的关系. 结果表明, 随着取代烷基链长度增加, t*和n值增大, R1/2减小, 动态表面活性降低. 由于双取代支链烷基苯磺酸钠分子具有特殊的柔性长支链, 使得吸附膜排列紧密、膜弹性增大, 因而其泡沫稳定性明显优于多取代直链烷基苯磺酸钠的稳定性. 在气流法产生泡沫的过程中, 动态表面张力是控制起泡高度的关键因素.     

CTAB水溶液表面的吸附动力学

用最大气泡压力法测定了十六烷基三甲基溴化铵(CTAB)水溶液的动态表面张力,研究了CTAB水溶液表面吸附的动力学及其影响因素。结果表明,吸附过程由初始的扩散控制经混合控制过渡到势垒控制。扩散控制吸附速率快,时间短;势垒控制速率慢,时间长,吸附势垒一般为4～10kJ.mol^-^1。温度升高,动态表面张力减小,但吸附机理不变;无机盐或醇类的加入对势垒值影响不大,但对扩散控制步骤的影响较大。     

三联阳离子表面活性剂的合成及复配性能

以环氧氯丙烷、叔胺、甘油为主要原料,水为溶剂,经过开环、季铵化反应,合成了新型三联季铵盐阳离子表面活性剂(Ⅲ-12-4),得率为86.9%。采用质谱和元素分析测试技术对产物结构进行表征,证明所得产物即为目标产物。通过采用DCA-315型表面张力及动态接触角分析仪对表面张力的测定研究了其与十二烷基硫酸钠(SDS)复配体系的表面化学性质,稳态荧光探针法考察了微极性变化,还得到了胶束聚集数。结果表明,复配体系与单一体系相比,具有更低的临界胶束浓度(cmc)和降低表面张力的效能,表现出协同效应。当n(Ⅲ-12-4)∶n(SDS)=3∶7时,复配体系的临界表面张力(γcmc)和临界胶束浓度分别为16.95mN/m和1.33×10-5mol/L,并且胶束聚集数只有SDS的1/6,混合胶束结构紧密,微极性降低。     

表面活性素分子结构对其胶束化行为的影响

采用表面张力、界面张力、荧光、动态光散射(DLS)和冷冻刻蚀电镜(FF-TEM)等方法, 研究了由Bacillus subtilis HSO121所产生的一组表面活性素的胶束化行为. 通过对表面活性素溶液表面张力、表面活性素对水/正己烷界面张力的影响、表面活性素胶束微极性以及胶束粒径和形态的研究, 发现随着表面活性素脂肪链长度的增加, 其表界面活性增强, 溶液中趋向于形成更大的聚集体.     

单油酸三羟甲基丙烷酯改性水性聚氨酯

利用单油酸三羟甲基丙烷酯(TMPM)、异佛尔酮二异氰酸酯(IPDI)和聚氧化丙烯(PPG)等制备水性聚氨酯。采用透射电镜(TEM)、动态激光光散射(DLLS)、红外光谱(FT-IR)、热重分析(TGA)和表面张力仪表征了乳液胶束形态、产物结构及性能。结果表明:水性聚氨酯(PU)分子上引入脂肪侧链容易在水中形成规整的胶束,但TMPM改性的水性聚氨酯胶束粒径随TMPM含量的增加不断增大,当w(TMPM)=0.07时,乳液不稳定;脂肪侧链的引入降低了水性聚氨酯乳液的表面张力,表面张力随着反应体系中—NCO和—OH摩尔比的增大而降低,随交联度的增大先增加后减小;TMPM的引入可以提高胶膜的热稳定性。     

二元醇水溶液性质与喷射性能研究

研究了具有相同碳链不同羟基位置的两种丙二醇(1,2-丙二醇和1,3-丙二醇)和三种丁二醇(1,3-丁二醇、2,3-丁二醇和1,4-丁二醇)对其水溶液保湿性、粘度、动态表面张力和喷射性能的影响。实验结果表明,相同碳链的二元醇中含伯羟基多的二元醇保湿性较差;每种二元醇水溶液随着二元醇浓度增加,粘度逐渐增加,表面张力逐渐降低,仲羟基在分子发生相对滑动时更容易使分子缠绕,体现为溶液的粘度大,含-CH_3基团的醇分子疏水性相对较强,使醇分子更多的在气液界面排列,表现为溶液表面张力较低;高频喷射时,溶液粘度接近时,表面张力大的溶液在喷射时容易离开喷嘴,液滴尾部获得初速度大,容易获得良好的液滴形态。     

A theoretical study on surfactant adsorption kinetics: effect of bubble shape on dynamic surface tension

A planar or spherical fluid-liquid interface was commonly assumed on studying the surfactant adsorption kinetics for a pendant bubble in surfactant solutions. However, the shape of a pendant bubble deviates from a sphere unless the bubble's capillary constant is close to zero. Up to date, the literature has no report about the shape effect on the relaxation of surface tension due to the shape difference between a pendant bubble and a sphere. The dynamic surface tension (DST), based on the actual shape of a pendant bubble with a needle, of the diffusion-controlled process is simulated using a time-dependent finite element method in this work. The shape effect and the existence of a needle on DST are investigated. This numerical simulation resolves also the time-dependent bulk surfactant concentration. The depth of solution needed to satisfy the classical Ward-Tordai infinite-solution assumption was also studied. For a diffusion-controlled adsorption process, bubble shape and needle size are two major factors affecting the DST. The existence of a needle accelerates the bulk diffusion for a small bubble; however, the shape of a large pendant bubble decelerates the bulk diffusion. An example using this method on the DST data of C12E4 is illustrated at the end of this work.     

Interfacial tensiometry method for the analysis of model systems in comparison with blood as the most important biological liquid

Interfacial tensiometry of various liquids is an informative colloid-chemical method for the analysis of various liquids in many areas of natural sciences and medical practice. This method of dynamic surface tension (DST) measurements is proposed for the study of animal blood plasma or serum and mixtures of proteins, lipids, and salts as model systems. It is found that the saline affects lecithin aqueous dispersions significantly more weakly than those of the proteins. The DST values and biochemical parameters of the bovine blood serum of the same sample are obtained. Correlations between DST values and biochemical parameters of blood serum are found. They are both of fundamental and practical importance in laboratory diagnostics.     

Thermal reversible gelation during phase separation of poly(N-isopropyl acrylamide)/water solution

By dynamic viscoelastic measurement for PNIPAM/water solution it has been found that below the phase separation temperature (about 32 ℃), the system is homogeneous fluid; while upon being heated to about 32 ℃, the solution undergoes phase separation and the storage modulus G' increases sharply and exceeds the loss modulus G", indicating the physical network formation during the phase separation. Based on the percolation model, the gel points Tgel, were obtained by applying the dynamic scaling theory (DST) and winter's criterion. The critical exponent n was also obtained to be 0.79 through DST, which is different from 0.67, the critical point of chemically crosslinked network predicted through DST. The obtained n value reflects the special property of physical network being different from chemical network.     

卤化钠对一种新型阳离子表面活性剂动态表面张力的影响

The equilibrium and dynamic surface tension （DST） of the novel cationic surfactant, 3-（p-nonylphenoxy）-2-hydroxylpropyl trimethyl ammonium bromide, abbreviated as RTAB, were studied. The effect of sodium halide such as NaCl, NaBr and NaI on the DST behavior of the RTAB solution below its CMC was studied in detail. Due to the preferential adsorption, the effect of hydration and salting out, the ability to reduce the DST values at the same concentration was in the order of NaI〉NaBr〉NaCl. Attributed to its high surface activity, the equilibrium time of the DST of the surfactant solution was insensitive to the ionic strength.     

Heterogeneous nucleation on the crystallization poly(ethylene terephthalate)

The crystallization behavior of poly(ethylene terephthalate) (PET) with disodium terephthalate (DST) as nucleating agent was investigated. A detailed analysis of the crystallization course from the melt was made with the Avrami expression. The results demonstrated that DST additive can promote the PET crystallization rate in its entire crystallizable temperature range, and the acceleration degree of DST decreases with increasing temperature after a temperature higher than 180 °C. The values of the Avrami exponent indicated that the crystallization mode in Avrami theory is not suitable for the crystallization of these polymers, and the mechanism of the heterogeneous nucleation on PET crystallization is discussed. © 2003 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 41: 2135–2144, 2003     

Dynamic surface tension parameters of protein–lipid–salt solutions as a system simulating blood plasma

Measurements of the dynamic surface tension (DST) of liquids is one of the simplest and fastest methods for the analysis of various chemical solutions and biological liquids. Solutions of the three-component systems on the basis of bovine serum albumin (BSA), natural phosphatidylcholine (PC), and sodium chloride are investigated. It is found that the salt content (especially at high concentrations) exerts a major impact during short time periods (0.1–1.0 s); and the BSA concentration, in intermediate and long time periods (over 1.0 s); however, changes in the PC concentration (in the range of concentrations typical for blood) insignificantly affect most of the DST parameters. The changes (by 22–68%) of the tensiogram slope values, λ₀, λ₁, and λ₂, are most informative among the seven studied DST parameters. This has allowed us to determine the optimal concentrations ranges for BSA (60–80 g/L), PC (1–4 mM), and NaCl (130–150 mM) in the mixture, which correspond to their content in the blood plasma of humans and animals. For four parameters, σ₁…σ₄, only small correlations with changes in the proportion of the three components in the mixture are found. The obtained relationships are important for both supplementing fundamental databases and prognostic modeling in biology and medicine.     

New methodology to determine the rate-limiting adsorption kinetics mechanism from experimental dynamic surface tension data

We present a new methodology to determine the rate-limiting adsorption kinetics mechanism (diffusion-controlled vs mixed diffusion-barrier controlled), including deducing the kinetics parameters (the diffusion coefficient, D, and the energy-barrier parameter, beta), from the experimental short-time dynamic surface tension (DST) data. The new methodology has the following advantages over the existing procedure used to analyze the experimental DST data: (a) it does not require using a model for the equilibrium adsorption isotherm, and (b) it only requires using the experimental short-time DST data measured at two initial surfactant bulk solution concentrations. We apply the new methodology to analyze the experimental short-time DST data of the following alkyl poly(ethylene oxide), CiEj, nonionic surfactants: C12E4, C12E6, C12E8, and C10E8 measured using the pendant-bubble apparatus. We find that for C12E4 and C12E6, the effect of the energy barrier on the overall rate of surfactant adsorption can be neglected for surfactant bulk solution concentrations below their respective critical micelle concentrations (CMCs), and therefore, that the rate-limiting adsorption kinetics mechanism for C12E4 and C12E6 is diffusion-controlled at any of their premicellar surfactant bulk solution concentrations. On the other hand, for C12E8 and C10E8, we find that their respective CMC values are large enough to observe a significant effect of the energy barrier on the overall rate of surfactant adsorption. In other words, for C12E8 and C10E8, the rate-limiting adsorption kinetics mechanism shifts from diffusion-controlled to mixed diffusion-barrier controlled as their premicellar surfactant bulk solution concentrations increase. We test the new methodology by predicting the short-time DST profiles at other initial surfactant bulk solution concentrations, and then comparing the predicted DST profiles with those measured experimentally. Very good agreement is obtained for the four CiEj nonionic surfactants considered. We also compare the results of implementing the new methodology with those of implementing the existing procedure, and conclude that using a model for the equilibrium adsorption isotherm can lead not only to different values of D and beta, but it can also lead to a completely different determination of the rate-limiting adsorption kinetics mechanism. Since the new methodology proposed here does not require using a model for the equilibrium adsorption isotherm, we conclude that it should provide a more reliable determination of the rate-limiting adsorption kinetics mechanism, including the deduced kinetics parameters, D and beta.     

Effect of humidity on the adsorption kinetics of lung surfactant at air-water interfaces

The in vitro adsorption kinetics of lung surfactant at air-water interfaces is affected by both the composition of the surfactant preparations and the conditions under which the assessment is conducted. Relevant experimental conditions are surfactant concentration, temperature, subphase pH, electrolyte concentration, humidity, and gas composition of the atmosphere exposed to the interface. The effect of humidity on the adsorption kinetics of a therapeutic lung surfactant preparation, bovine lipid extract surfactant (BLES), was studied by measuring the dynamic surface tension (DST). Axisymmetric drop shape analysis (ADSA) was used in conjunction with three different experimental methodologies, i.e., captive bubble (CB), pendant drop (PD), and constrained sessile drop (CSD), to measure the DST. The experimental results obtained from these three methodologies show that for 100% relative humidity (RH) at 37 degrees C the rate of adsorption of BLES at an air-water interface is substantially slower than for low humidity. It is also found that there is a difference in the rate of surface tension decrease measured from the PD and CB/CSD methods. These experimental results agree well with an adsorption model that considers the combined effects of entropic force, electrostatic interaction, and gravity. These findings have implications for the development and evaluation of new formulations for surfactant replacement therapy.