反离子对氟表面活性剂的影响1. 表面活性及胶团化作用

通过表面张力和荧光探针法研究了全氟辛酸钠、全氟辛酸铵以及全氟辛酸四烷基铵[C₇F₁₅COON(C_nH_2n+1)₄, n＝1, 2, 3, 4]的表面活性以及胶团化作用, 系统地讨论了各种反离子, 特别是反离子大小的影响. 结果表明, 与普通碳氢表面活性剂不同, 反离子对这类氟表面活性剂的表面活性以及胶团化作用有很大影响. 表面活性剂的临界胶束浓度(cmc)随反离子的增大而下降; 饱和吸附层中平均每个分子所占的面积则大致随反离子的增大而增大. 而表面张力的变化则较为复杂. cmc时的表面张力随反离子的增大先上升(从全氟辛酸铵到全氟辛酸四乙铵)后下降(从全氟辛酸四乙铵到全氟辛酸四丁铵). 通过反离子的空间位阻、疏水性、插入以及电荷屏蔽效应对上述结果做了解释.     

全氟烷基磺酸盐和全氟烷基磺酰亚胺盐的多相化催化研究

传统的Lewis酸催化剂在环境的压力下受到挑战,全氟烷基磺酸盐和全氟烷基磺酰亚胺盐作为均相、高效的Lewis酸催化剂在有机合成中受到人们的关注.为了简化分离操作,人们对全氟烷基磺酸盐和全氟烷基磺酰亚胺盐的多相化进行了研究,并已取得巨大进展.本文综述了全氟烷基磺酸盐和全氟烷基磺酰亚胺盐分别负载在有机载体、无机载体以及离子液体上的多相化催化最新研究进展,简要概括了其制备方法和催化活性,并对其催化应用前景进行了展望.     

反离子对全氟辛酸盐与高聚物的相互作用的影响

通过表面张力和电导率测定, 研究了全氟辛酸铵/四烷基铵(C7F15COON(CnH2n＋1)4, n＝0, 1, 2, 3, 4)与聚氧乙烯(PEO, 分子量20000)和聚氧乙烯聚氧丙烯三嵌段共聚物(Pluronic F68)的相互作用. 结果表明, 对PEO-C7F15COON(CnH2n＋1)4混合体系, 只有全氟辛酸铵、全氟辛酸四甲铵与PEO之间有明显的相互作用. 对F68-C7F15COON(CnH2n＋1)4混合体系, 只有全氟辛酸四丁铵未发现与F68有明显的相互作用. 说明全氟辛酸盐的反离子越大, 其与高聚物间的相互作用越弱. 增加高聚物的疏水性可以增强表面活性剂与高聚物的相互作用.     

加盐导致的全氟辛酸盐表面活性的反常行为

通过测定全氟辛酸铵(APFO)、全氟辛酸三甲铵(TMHPFO)、全氟辛酸三乙铵(TEHPFO)在不同浓度NaCl (0.1, 0.3, 0.5 mol•L^－1)存在时水溶液的表面张力曲线, 考察不同反离子的氟表面活性剂其表面活性随无机盐浓度的变化. 结果表明, NaCl对APFO的胶束化有明显的促进作用|对于TMHPFO和TEHPFO则在NaCl浓度较低时有很小的促进作用, NaCl浓度较高时由于Na^＋和N(CH₃) (或N(CH₂CH₃) )之间的离子交换作用反而临界胶束浓度(cmc)增大. APFO, TMHPFO的最低表面张力(γ_cmc)随着NaCl浓度的增大而增大. 而对于TEHPFO, 少量NaCl的加入有利于降低γ_cmc、然后随着NaCl浓度的增大TEHPFO的γ_cmc增大. 这说明, 加盐溶液中始终存在着屏蔽效应和离子交换作用的竞争, 随着NaCl浓度增大离子交换趋势增大|对于疏水性较高的三乙铵离子在NaCl存在的情况下离子交换作用导致的γ_cmc升高需要更高的NaCl浓度才能显现. 通常认为外加无机盐是增强表面活性剂的表面活性的方法之一, 本工作表明, 对于有些反离子为有机阳离子的氟表面活性剂, 外加无机盐, 如NaCl, 不仅不能起到显著的增效作用, 浓度大时甚至会降低表面活性剂的效能. 所以这类表面活性剂在实际使用时应尽量避免高盐环境.     

ω-氯代氧杂全氟羟酸及其与溴化辛基三甲铵混合体系的表面化学性质研究

对ω-氯代氧杂全氟羟酸(ClCF)与溴化辛基三甲铵(C8N)混合体系的表面活性和泡添性质进行了研究。溶液表面张力测定的结果表明, ClCF及其混合体系有很低的监界胶团浓度(cmc)和γcmc值, 即有很高的表面活性。ClCF溶液有很好的起泡性能, 但ClCF-C8N混合体系与一般正负高子表面活性剂混合体系迥异, 显示出ω-氯代结构的特殊影响。     

ω-氯代氧杂全氟羟酸及其与溴化辛基三甲铵混合体系的表面化学性质研究

对ω-氯代氧杂全氟羟酸(ClCF)与溴化辛基三甲铵(C8N)混合体系的表面活性和泡添性质进行了研究。溶液表面张力测定的结果表明, ClCF及其混合体系有很低的监界胶团浓度(cmc)和γcmc值, 即有很高的表面活性。ClCF溶液有很好的起泡性能, 但ClCF-C8N混合体系与一般正负高子表面活性剂混合体系迥异, 显示出ω-氯代结构的特殊影响。     

全氟辛酸铵与全氟壬酸铵混合物的表面活性

测定了全氟辛酸铵和全氟壬酸铵及其不同比例混合物的0.1mol/L氯化铵水溶液表面张力曲线。讨论了它们的胶团化作用、吸附作用和降低水表面张力的能力。改进了Ingram-Luckhurst自单一表面活性剂活性张力曲线得到混合溶液表面张力曲线的方法。     

不等链长的碳氟、碳氢正负离子表面活性剂混合体系的表面活性

研究了全氟辛酸钠与溴化十四烷基三甲铵混合水溶液的表面活性. 测定了不同比例混合物水溶液的表面张力-浓度曲线, 得出临界胶团浓度(cmc)及监 界胶团浓度时的溶液表面张力(γcmc)值. 应用Gibbs吸附公式及吸附层中两表面活性剂分子相互作用参数法求出表面总吸附量、吸附层组成及两表面活性剂分别吸附量等. 指示此吸附层具有多分子层性质. 这可能是碳氢、碳氟正负离子混合体系的特点.     

全氟辛酸盐胶束对芘的加溶研究

胶束微观极性与微观粘度等微环境性质的研究近来已引起人们越来越广泛的注意。已有的研究工作主要限于碳氢表面活性剂体系,全氟表面活性剂体系的研究为数甚少。通常认为全氟表面活性剂有疏油性,因而对于全氟表面活性剂胶束能否加溶碳氢有机物,加溶部位胶束微环境性质如何,各种利用有机探针分子的光物理方法能否用于全氟胶束的物理化学性质的研究等问题很少有研究工作报道。本文研究了全氟辛酸盐胶束加溶芘的特性。实验     

α-芳基-α-羟基酮(酯)与全氟烷基磺酰氟/甲基三乙氧基硅烷/碱体系不期望的氧化反应

研究了全氟烷基磺酰氟/甲基三乙氧基硅烷/碱体系与α-芳基-α-羟基酮(酯)化合物不期望的氧化反应,以中等到优良的收率生成了相应的1,2-二酮(α-酮酸酯)产物.所用全氟烷基磺酰氟为全氟正丁基磺酰氟或全氟正辛基磺酰氟;碱为1,8-二氮杂二环[5.4.0]十一碳-7-烯(DBU).提出了一种可能的反应机理.为制备芳基取代的1,2-二酮(或α-酮酸酯)化合物提供了一种新方法.     

辛基甲基亚砜与离子型表面活性剂在水溶液中的相互作用

本文用测定表面张力的方法研究了非离子表面活性剂辛基甲基亚砜(OMS)分别与离子型表面活性剂C_(10)H_(21)SO_4N_a(SDeS)、C_7F_(15)COONa(SPFO), C_(10)H_(21)N(CH_3)_3B_r(DeTAB)等在水溶液中的相互作用。发现上述混合体系的胶团形成及表面吸附都有不同程度的增效作用; 表面活性分子在吸附层中的相互作用参数β~s以及在胶团中的相互作用参数β~m均为负值并有一定变化规律; OMS与DeTAB的相互作用较OMS与SDeS或SPFO的相互作用弱得多; 此现象自OMS分子在水溶液中的质子化作用得到解释。     

Synthesis and evaluation of some polymeric surfactants for treating crude oil—Part II. Destabilization of naturally occurring water‐in‐oil emulsions by polyalkylphenol formaldehyde amine resins

In the present work, three polymeric surfactants were prepared and used as demulsifiers; polyalkyl phenol formaldehyde monoethanol amine ethoxylate, eo, 136(D1), polyalkyl phenol formaldehyde diethanol amine ethoxylate, eo, 37(D2) and polyalkyl phenol formaldehyde triethanol amine ethoxylate, eo, 21.5(D3). Their demulsification potency in breaking water‐in‐crude oil emulsions was investigated. In this respect, two naturally occurring Egyptian water‐in‐oil (w/o) emulsions, one of them was waxy and the other was asphaltenic, were used in order to study the demulsification power of these compounds. The data revealed that, the resolution of water from waxy crude emulsion was easier than asphaltenic crude emulsion. The demulsification efficiency increases with increasing demulsifier concentration, contact time and temperature. The interfacial tension (IFT) at the crude oil–water interface was measured, it was found that the concentration of demulsifiers required to cause a minimum IFT are always less than these indicating a maximum demulsification efficiency. All the results were discussed in relation to emulsifier chemical structure and crude oil composition. Copyright © 2002 John Wiley & Sons, Ltd.     

A Study of the Electrochemical Behavior of Copper in Acid Medium in Presence of Some Organic Amine Compounds

The rate of corrosion of copper metal in presence of methyl amine, dimethyl amine, diethyl amine, triethyl amine, diethanol amine, and triethanol amine determined by measuring the anodic limiting current. The factors used are type of organic amine compounds and its concentration, concentration of H₃Po₄, viscosity of solution, density, diffusion coefficient, and rate of rotation. It has been found that, the rate of corrosion decrease in presence of these compounds. The inhibition percentage ranged from 9.72% to 80.14% depending on the type of inhibitor and its concentration. It is suggested that the decrease in the rate of corrosion is attributed to the increase in interfacial viscosity of the solution and decrease the diffusion coefficient of the copper ion. It has been found that we can apply the Langmuir, Flory-Huggins, and kinetic adsorption isotherms. It has been found that the rate of inhibition is increases in order: methyl amine, dimethyl amine, diethyl amine, triethyl amine, diethanol amine, and triethanol amine. The rate of corrosion depends on the H₃Po₄ concentration as well as on the electrode height. The limiting current in undivided cells is higher than in divided cells due to the uprising H₂ bubbles, which enhances the rate of corrosion. Also, the rate of corrosion was found to increase by increasing the speed of rotating electrode. The dimensionless groups were calculated, and the relation between them was given and the equation given as following: Sh = 0.5046 Re^0.7201(Sc)^0.33 for methyl amine; Sh = 0.5381 Re^0.7157(Sc)^0.33 for dimethyl amine; Sh = 0.4887 Re^0.7356(Sc)^0.33 for diethyl amine; Sh = 0.5167 Re^0.7207(Sc)^0.33 for triethyl amine; Sh = 0.5373 Re^0.7238(Sc)^0.33 for diethanol amine; and Sh = 0.4958 Re^0.7280(Sc)^0.33 for triethanol amine.     

Effect of counterions on surface and foaming properties of dodecyl sulfate

The influence of counterions of surfactant on interfacial properties is studied by measuring foamability, foam stability, equilibrium and dynamic surface tension, and surface viscosity. The surfactant chosen is anionic dodecyl sulfate with various counterions, Li(+), Na(+), Cs(+), and Mg(++). Surface tension measurements show a decrease in the following order: LiDS > NaDS > CsDS > Mg(DS)(2). Foamability done using shaking method shows similar order as surface tension, i.e., LiDS > NaDS > CsDS > Mg(DS)(2). This has been explained in terms of the differences in micellar stability and diffusion of monomers. This is further confirmed by our dynamic surface tension results, which show the same order as equilibrium surface tension (i.e., LiDS > NaDS > CsDS > Mg(DS)(2)) at low bubble frequencies but the order is LiDS > NaDS = Mg(DS)(2) > CsDS at high bubble frequencies. Foam stability measurements were done at concentrations below and above cmc to elucidate the role of micelles. It was found that there is no significant change in foam stability when counterions are changed for surfactant concentration values below the cmc, but at concentration above cmc the foam stability of CsDS and Mg(DS)(2) are much greater than LiDS and NaDS indicating presence of stable micelles are essential to high foam stabilities. Surface viscosity measurements correlated well with the foam stability trends and gave the following order LiDS < NaDS < CsDS < Mg(DS)(2), indicating that the molecules of CsDS and Mg(DS)(2) are tightly packed at the air/water interface.     

Salt-induced phase inversion in aqueous cationic/anionic surfactant two-phase systems

Phase inversion of aqueous two-phase systems with excess cationic surfactant (abbreviated as ATPS-C) formed by aqueous mixtures of 1,3-propanediyl bis(dodecyl dimethylammonium bromide) (abbreviated as 12-3-12) and sodium dodecyl sulfonate (abbreviated as AS) at 318.15 K was investigated. The experimental results indicate that addition of NaF, NaCl, NaHCO 3, or NaNO 3 can result in phase inversion of ATPS-C formed by 12-3-12/AS systems; however, addition of NaBr cannot lead to phase inversion. TEM micrographic experiments illustrate that there is no direct relationship between the microstructures of the concentrated phase in ATPS-C and phase inversion. To interpret the phase-inversion phenomena of ATPS-C, the phase composition, phase density, and phase volume ratio between the dilute phase and the concentrated phase in ATPS-C were investigated. Phase composition analysis results illustrate that for the ATPS-C formed by 0.10 mol.kg (-1) 12-3-12/AS mixed system, the concentration of Br (-) counterions in the dilute phase of ATPS-C increases with addition of NaF, NaCl, NaHCO 3, or NaNO 3. At the same time, the molar ratio between the F (-) (Cl (-), HCO 3 (-), or NO 3 (-)) counterions and Br (-) counterions in the concentrated phase of ATPS-C increases also. It illustrates that part of the bromide counterions which are the natural counterions of the surfactant 12-3-12 in excess are exchanged by other anionic counterions when an additional salt is added to the system. The investigation indicates that the common ground of the added F (-), Cl (-), HCO 3 (-), or NO 3 (-) counterions is that they all make a smaller density contribution than that of Br (-) counterions, although they have a weaker or stronger counterion binding ability with the mixed positively charged aggregates in ATPS-C than that of Br (-) counterion. Density experiments illustrate that the density increase of the dilute phase is larger than that of the concentrated phase in the ATPS-C with addition of NaF, NaCl, NaHCO 3, or NaNO 3; thus, phase inversion occurs. The densities of the added inorganic sodium salt aqueous solution and the order of the Hofmeister series for the added inorganic anions with respect to the chaotropic headgroup of 12-3-12 play important roles in the phase inversion of ATPS-C.     

阳离子碳氟表面活性剂研究I: 水溶液中的胶束特性及生长

利用动态光散射(Dynamic Light Scattering, DLS)、瞬态电双折射(Transient Electric Birefringence, TEB)和粘度测定方法研究了部分氟代阳离子表面活性剂氟代-2-羟基十一烷基二乙羟基甲基氯化铵(diethanolheptadecafluoro-2-undecanol methylammonium chloride, C₈F₁₇CH₂CH(OH)CH₂NCH₃(C₂H₄OH)₂Cl, DEFUMACl)水溶液的胶束化特性. 结果表明: DEFUMACl的临界胶束浓度cmc为3.8 mmol•L^－1. 稀溶液中随着DEFUMACl浓度的增加或者无机盐NaCl的加入, DEFUMACl胶束由球形向棒状转变, 其转变浓度, 即第二临界胶束浓度(cmc_II)为0.2 mol•L^－1; 电导测定的反离子(Cl^－)结合度为0.72. 利用球形和棒状胶束模型确定的DEFUMACl胶束聚集数分别为45和335.     

Phenyl-ring-bearing cationic surfactants: effect of ring location on the micellar structure

A series of isomeric cationic surfactants (S1-S5) bearing a long alkyl chain that carries a 1,4-phenylene unit and a trimethyl ammonium headgroup was synthesized; the location of the phenyl ring within the alkyl tail was varied in an effort to understand its influence on the amphiphilic properties of the surfactants. The cmc's of the surfactants were estimated using ionic conductivity measurements and isothermal calorimetric titrations (ITC); the values obtained by the two methods were found to be in excellent agreement. The ITC measurements provided additional insight into the various thermodynamic parameters associated with the micellization process. Although all five surfactants have exactly the same molecular formula, their micellar properties were seen to vary dramatically depending on the location of the phenyl ring; the cmc was seen to decrease by almost an order of magnitude when the phenyl ring was moved from the tail end (cmc of S1 is 23 mM) to the headgroup region (cmc of S5 is 3 mM). In all cases, the enthalpy of micellization was negative but the entropy of micellization was positive, suggesting that in all of these systems the formation of micelles is both enthalpically and entropically favored. As expected, the decrease in cmc values upon moving the phenyl ring from the tail end to the headgroup region is accompanied by an increase in the thermodynamic driving force (ΔG) for micellization. To understand further the differences in the micellar structure of these surfactants, small-angle neutron scattering (SANS) measurements were carried out; these measurements reveal that the aggregation number of the micelles increases as the cmc decreases. This increase in the aggregation number is also accompanied by an increase in the asphericity of the micellar aggregate and a decrease in the fractional charge. Geometric packing arguments are presented to account for these changes in aggregation behavior as a function of phenyl ring location.