油酸钠／水／十六烷／4—烯丙基—4—羟基—1,6—庚二烯体系层 …

将十六烷增溶于油酸钠／水体系层状液晶的油层,共聚单体４－烯丙基－４－羟基－１,６－庚二烯增溶于油酸钠／水体系层状液晶的两亲层,在同一两亲层内进行共聚反应,得到了具有层状结构、并具有较好表面活性的共聚物。     

油酸钠层状液晶体系的聚合

将十六烷增溶于油酸钠／水体系层状液晶的油层,共聚单体二乙烯基乙二醇增溶于油酸钠／水体系层状液晶的两亲层,将共聚限制在同一两亲层内油酸钠的双键与共聚单体之间进行。得到了具有层状结构,并具有较好表面活性的共聚物。     

油酸钠/水/十六烷/三丙烯酸季戊四醇酯体系层状 液晶的聚合

将十六烷增溶于油酸钠(NaOL)/水体系层状液晶的油层,共聚单体三丙烯酸季戊四醇酯(PETA)增溶于油酸钠/水体系层状液晶的两亲双层。72℃下,以增容于油层中的十六烷作为阻隔。在层状液晶同一两新双层内的两新分子油酸钠与共聚单体PETA之间进行共聚,得到了具有层状结构、并具有较好表面活性的共聚物。     

Brij35／油酸钠／油酸／水体系的溶致液晶性质——应用偏光显微镜,SAXS,~2H-NMR和流变等方法

首先研究Brij35(十二烷基聚氧乙烯(23)醚)/油酸钠/油酸/水体系的拟三元相图, 发现该体系最大的特点是溶致液晶占相图总面积的2/3. 对O/W型微乳液进行流动曲线研究, 属于牛顿流体. 对溶致液晶体系开展了偏光显微镜, SAXS, ²H-NMR等方法的研究. 当体系组成沿着相图中AA¢线改变时, 其液晶结构变化的顺序是, 立方状液晶→立方状与层状液晶共存→层状液晶→层状液晶与六角状液晶共存→六角状液晶. 并且对上述体系系统地开展了流变性质的研究. 其结果再一次证实液晶结构随着体系中某组分的改变而发生变化. 同时还得到立方液晶和六角状液晶的晶格参数, 分别为10.53和5.68 nm.     

非水层状液晶的结构与稳定性 Ⅲ.三乙醇胺油酸盐层状液晶及其增溶特性

Friberg曾以等摩尔的三乙醇胺(TEA)与油酸(OLA)混合,生成了三乙醇胺油酸盐(TEA-OLA)非水层状液晶,并指出在TEA的作用下,大部分OLA去质子,生成了三乙醇胺油酸盐,组成层状液晶两亲双层,剩余的TEA、OLA作为溶剂存在于层状液晶的溶剂层中,本文报道以甲酰胺(FA)为溶剂时TEA-OLA与TEA-OLA/FA层状液晶的生成范围及其稳定性。     

油酸/三乙醇胺/液体石蜡水体系层状润滑性能

层状液晶;油酸/三乙醇胺/液体石蜡水体系层状润滑性能     

Triton X-100体系层状液晶结构及其润滑性能

用小角X射线衍射和2HNMR方法测定TritonX 100/n C10H21OH/H2O体系层状液晶的结构.用高速环块磨损验机考察了不同组分含量的层状液晶对铝合金 钢磨擦副润滑性能的影响.结果表明:随着水含量的增加,层液晶两亲双层中分子的有序度降低,润滑效果也降低;随着Tri tonX 100含量增加,层状液晶两亲双层中分子有序度增加,其润滑效果提高.     

Triton X－100／C_（10）H_（21）OH／H_2O体系层状液晶中水溶性超微粒子材料Na_2C_2O_4的制备

利用溶剂在层状液晶中的渗透性和层状液晶中溶剂层厚度的限定性，在ＴｒｉｔｏｎＸ－１００／Ｃ_（１０）Ｈ_（２１）ＯＨ／Ｈ_２Ｏ体系层状液晶中，以饱和Ｎａ_２Ｃ_２Ｏ_４水溶液代替组分水制备水溶性超微粒子材料Ｎａ_２Ｃ_２Ｏ_４，平均粒径约为６ｎｍ．     

Triton X-100/C10H21OH/H2O体系层状液晶中超微粒子材料PbS的合成

将Pb(NO3)2和Ns2S分别溶于Triton X-100/C10H21OH/H2O体系层状液晶溶剂层中, 混和即可在溶剂层中生成PbS粒子, 并以层状液晶中溶剂层厚度的大小, 限定所合成PbS粒子的尺寸小于10nm, 改变有关组分含量对PbS超微粒子大小无显著影响, 所合成PbS超微粒子的平均粒径均小于10nm.     

非水层状液晶的稳定性与相行为

水体系层状液晶已研究较久,非水层状液晶则是近十年来才得到发展。本文以层状液晶的相行为和~2H NMR测量,研究并比较了非水层状液晶十二烷基硫酸钠/正癸醇溶剂以甘油或甲酰胺为溶剂时体系的结构与稳定性。 表面活性剂十二烷基硫酸钠(BDH,简写SDS)经无水乙醇重结晶两次提纯。用铂环法测     

Lamellar liquid crystal polymerization of sodium oleate/oleic acid/octadiene/water system

In the lamellar liquid crystallization (LLC) phase of NaOL/ OLA/H2O system, the small angle X-ray diffraction measurements show that the oleic acid is solubilized in the oil layer at first and then into the amphiphile layer. The octadiene added is also located partly in the oil layer and partly in the amphiphile layer in the LLC. With the addition of octadiene as cross-Unking agent, the LLC phase of NaOL/OIA/H2O system was polymerized under the initiation of AIBN with the protection of pure nitrogen at 60℃. Most of the double bond absorption of the monomers in IR spectra disappeared after polymerization. The polymerization takes place not only in the middle of the amphiphile layer between the double bonds of NaOL or OLA and those of octadiene, but also in the oil layer of LLC between the double bonds of OLA and those of octadiene. Interlayer spacing measurements on the copolymer proved d values decreased by about 1-2 nm compared with those of the corresponding system before the polymerization, indicati     

Structural changes induced by addition of a hydrocarbon to water/amphiphile mixtures

The phase conditions in a system of water, hexadecane, sodium dodecyl sulphate, and di-ethylene glycol dodecyl ether showed theW/O microemulsions to be obtained first after destabilization of a liquid crystalline phase by addition of the hexadecane. The original lamellar liquid crystalline phase was moved towards higher surfactant/cosurfactant ratios and a new phase with inverse amphiphile cylinders in a hexagonal packing appeared.     

Alignment of liquid crystals induced by a photopolymerized self‐assembled film

An alignment film derived from a photopolymerized self‐assembled film may be used to orient nematic liquid crystals after irradiating the film with linearly polarized UV (LPUV). A photosensitive cationic amphiphile was first synthesized containing two double bonds and which could be polymerized by UV. A layer‐by‐layer self‐assembled multilayer film was next prepared in an aqueous solution of the cationic amphiphile and poly(sodium 4‐styrenesulphonate); the UV‐Vis spectra showed that each layer of the LBL multilayer film was uniform. When the film was irradiated by LPUV, the photosensitive double bonds underwent [2+2] cycloaddition along the vector direction of LPUV. The polarized UV‐Vis absorption spectra also provided evidence that the film was anisotropic, i.e. the photopolymerization was along a certain direction. The anisotropic film was used as an alignment layer for nematic liquid crystals, and observations under a polarizing microscope indicated that the alignment of the liquid crystals was good, as expected, and that the orientation direction of the liquid crystals was always perpendicular to the electric vector of the irradiating LPUV.     

Alignment of liquid crystals induced by a photopolymerized self-assembled film

An alignment film derived from a photopolymerized self-assembled film may be used to orient nematic liquid crystals after irradiating the film with linearly polarized UV (LPUV). A photosensitive cationic amphiphile was first synthesized containing two double bonds and which could be polymerized by UV. A layer-by-layer self-assembled multilayer film was next prepared in an aqueous solution of the cationic amphiphile and poly(sodium 4-styrenesulphonate); the UV-Vis spectra showed that each layer of the LBL multilayer film was uniform. When the film was irradiated by LPUV, the photosensitive double bonds underwent [2+2] cycloaddition along the vector direction of LPUV. The polarized UV-Vis absorption spectra also provided evidence that the film was anisotropic, i.e. the photopolymerization was along a certain direction. The anisotropic film was used as an alignment layer for nematic liquid crystals, and observations under a polarizing microscope indicated that the alignment of the liquid crystals was good, as expected, and that the orientation direction of the liquid crystals was always perpendicular to the electric vector of the irradiating LPUV.     

Synthesis and lyotropic liquid crystalline behaviour of a taper-shaped phosphonic acid amphiphile

A taper-shaped phosphonic acid, 3,4,5-tris(dodecyloxy)phenylmethylphosphonic acid ( 1 ), was synthesized; its lyotropic liquid crystalline (LLC) behaviour and its ability simultaneously to order and acid-dope polyaniline were examined. It was found that the ability of 1 to form LLC phases in the presence of several hydrophilic solvents is restricted by strong intermolecular interactions between the phosphonic acid head groups (presumably H-bonding). The amphiphile exhibits poor miscibility with pure water and even with strong H-bonding organic solvents such as DMF. However, it forms a lamellar mesophase in the presence of aqueous acid. Upon deprotonation of the phosphonic acid head group with NaOH, the resulting disodium salt of the amphiphile is able to form a well defined lamellar phase with pure water. The propensity of 1 to form lamellar phases is somewhat unusual since its tapered molecular shape should direct it to form an inverted hexagonal LLC phase. These results suggest that intermolecular head group interactions are more important in determining the overall LLC behaviour of this phosphonic acid amphiphile than are the hydrophobic character and shape of the organic tail system. Compound 1 was also found to be sufficiently acidic to act as an acid dopant for the conjugated polymer polyaniline in the emeraldine base form. LLC acid 1 induces the resulting polymeric salt to form an electrically conductive LLC complex with an extended lamellar microstructure. The bulk conductivity of the resulting nanostructured polyaniline salt was found to be only in the semiconducting regime (10 -5 Scm -1 ), due to an unfavourable polyaniline chain conformation in the LLC complex.     

POLYMERIC SURFACTANTS BASED ON OLEIC ACID IV. Lamellar Liquid Crystal Polymerization of Sodium Oleate/Oleic Acid/Aliphatic Diene/Water System

The lamellar liquid crystalline phase in the system consisting of sodium oleate (NaOL), oleic acid (OLA), and water was determined. The interlayer spacing (d) of the lamellar liquid crystal was measured through small angle X-ray diffraction, which indicated that oleic acid molecules were solubilized between the end methyl groups at low concentrations, and then were located within the hydrocarbon chain layer with further increase of its concentration. Cross-linking agents were added to the system, which were found being located partly in between the end methyl groups and partly within the hydrocarbon chain layers. The liquid crystal phase of NaOL/OLA/H₂O system with the cross-linking agent was polymerized at 60 °C, which turned out to be a mixture of liquid crystals and solids. Interlayer spacing decreased by about 10 Å, indicating a disruption of the ordered structure by the polymerization. The polymerization took place not only within the hydrocarbon layer, but also in between the layers separated by the end methyl groups. The resulting polymer lowered the surface tension of water to below 30 mN/m, with a critical micellization concentration of about O.25g/L.     

Contact of oil with solid surfaces in aqueous media probed using sum frequency generation spectroscopy

We have studied the interface between hexadecane droplets and sapphire substrates in water using infrared-visible sum frequency generation spectroscopy (SFG). At high pH and above the isoelectric point of the sapphire substrate, the hexadecane drop is repelled due to electrostatic forces. The SFG measurements are consistent with the observation that a thick layer of water is present between the oil and the sapphire substrate. Below the isoelectric point of the sapphire substrate, the hexadecane drops stick to the sapphire surface. Surprisingly, the SFG results show the presence of a thin layer of water between hexadecane drop and the sapphire substrate. At this contact interface, we observe contributions to the SFG signal from both the hexadecane/water and water/sapphire interfaces. The reasons for the presence of a thin water layer with adhesive contact can be explained due to weaker repulsive double layer and the attractive van der Waals interactions.     

Extraction of europium by sodium oleate/pentanol/heptane/NaCl microemulsion system

The extraction of europium to a W/O microemulsion with an anionic surfactant was studied. In the sodium oleate (NaOL)/pentanol/heptane/NaCl system, the influence of aqueous-microemulsion ratio, concentration of NaOL, extraction temperature, concentration of cosurfactant, pH and salting-out agent on the extraction yield were investigated. Europium was probably extracted into the microemulsion phase in the form of Eu(OL)₂Cl, and the extraction yield (E%) was above 99% when R = 8. The enthalpy and entropy of Eu(III) extraction were calculated to be −12.18 kJ/mol and −61.41 J/(mol K), respectively. The back-extraction is conducted by hydrochloric acid (0.8 mol/L), which provided better back-extraction yields (95.15%).