SiO2载负回收全氟磺酸树脂催化乙酸丁酯合成

SiO2载负回收全氟磺酸树脂催化乙酸丁酯合成;固体酸;全氟磺酸树脂/二氧化硅复合物催化剂     

新形态全氟磺酸树脂催化剂研究进展

全氟磺酸树脂是绿色固体酸催化剂，对许多反应有较好的催化活性和选择性。但由于全氟磺酸树脂比表面较低，埋没在氟碳基体中的酸性中心不易被反应物所接近，质量比活性低。本文对近年来新形态全氟磺酸树脂，如多孔、负载化、纳米复合物及其改性的全氟磺酸树脂的催化作用进行了综述，文献结果表明全氟磺酸树脂纳米复合物对很多有机合成反应具有很高的催化活性。     

阳离子交换树脂的有机催化进展

综述了聚苯乙烯型磺酸树脂、全氟磺酸树脂Nafion及崭新的Nafion／siO_2复 合催化剂在有机合成中应用的最新进展．     

全氟磺酸树脂/二氧化钛杂化薄膜的制备与表征

利用可溶性全氟磺酸树脂和二氧化钛前躯体钛酸丁酯液-液相体系, 结合蒸汽水热结晶方法制备了全氟磺酸树脂/二氧化钛杂化薄膜, 并通过扫描电子显微镜(SEM)、X-射线衍射(XRD)、红外光谱分析仪(FT-IR)及紫外-可见分光光度计(UV-vis)等测试方法对杂化薄膜的形貌、晶型、结构及光学性能进行了表征. 结果表明: 蒸汽水热结晶法能促进全氟磺酸树脂/二氧化钛杂化薄膜的结晶和相变; 水热后该杂化薄膜表面平整光滑, 没有裂纹, 二氧化钛晶型为锐钛矿并以球形微粒均匀分散在全氟磺酸树脂基体中; 随着杂化体系中二氧化钛含量的增多, 其粒径逐渐减小、团聚现象消失且杂化薄膜的紫外吸收性能显著提高.     

全氟磺酸离子交换膜的制备与性能研究

采用四氟乙烯、六氟丙烯和全氟磺酰基乙烯基醚共聚合成了全氟磺酸离子交换树脂,通过溶液浇铸法将其制成全氟磺酸离子交换膜(PSALM)。PSALM膜显示出优良的力学性能、电化学性能以及化学稳定性。TGA测试结果表明,PSALM膜的初始热分解温度超过400℃;DSC测试结果显示,膜中存在微观相分离,该膜具有三个热转变温度,分别对应于非晶区、离子簇区和结晶区。     

用Nicolet 60SXB FTIR光谱仪研究全氟磺酸树脂中的不稳定端基的热行为

本文用付立叶变换红外光谱法研究了全氟磺酸树脂中不稳定端基的分解程度与热压成膜温度之间的关系,发现在全氟磺酸树脂的红外光谱中位于1812cm~(-1)处的游离的不稳定羧端基受热分解是造成树脂热压成膜产品中存在大量气泡的主要原因,而且当热压成膜温度增加时,1812cm~(-1)处吸收峰减小,而位于1776cm~(-1)处则产生一个新的吸收峰,两者之间有较好的规律性。同时还发现,树脂在热压成膜过程中存在着两个游离的不稳定端基之间的化合反应。     

几种典型含氟树脂流变行为研究概述

主要对乙烯-四氟乙烯共聚物(ETFE)、聚全氟乙丙烯(FEP)、聚偏氟乙烯(PVDF)、全氟磺酸树脂(PFSA)和全氟羧酸树脂(PFCR)这几种典型含氟树脂的加工流变行为和线性粘弹性进行了综述。FEP高速挤出时稳定流动区非常窄,并且进行模型拟合时发现其剪切流动行为符合Carreau模型。ETFE为热流变简单高分子,其剪切粘度、拉伸粘度、挤出胀大和动态模量等流变函数均可进行时温叠加。在低剪切速率下,PVDF熔体表现出牛顿流体行为;在高剪切速率下,PVDF熔体呈现出剪切稀化现象。PFSA和PFCR熔体的表观黏度随剪切速率、温度的升高而降低,流动曲线显示该熔体属于假塑性流体。     

全氟辛基磺酸稀土金属盐催化氟两相Friedel-Crafts烷基化反应

全氟辛基磺酸稀土金属盐催化氟两相Friedel-Crafts烷基化反应;氟两相催化;全氟辛基磺酸稀土金属盐;全氟溶剂;Friedel-Crafts烷基化     

全氟辛基磺酸稀土金属盐催化氟两相Friedel-Crafts酰化反应

全氟辛基磺酸稀土金属盐催化氟两相Friedel-Crafts酰化反应;氟两相催化;全氟辛基磺酸稀土金属盐;全氟溶剂;Friedel-Crafts酰化     

固体超酸POSA催化醇脱水制烯

固体超酸由于其优良的催化性能,近年来倍受重视。其中以全氟骨架的磺酸树脂Nafion H应用最广。POSA(全氟辛基磺酸,C_8F_(17)SO_3H)也是一种化学性质稳定、易回收的固体超酸,具有与Nafion H相似的氟碳链磺酸结构。     

Nonisothermal membrane phenomena across perfluorosulfonic acid-type membranes,Flemion S: part I. Thermoosmosis and transported entropy of water

Solvent transports across the perfluorosulfonic acid-type membrane Flemion S were measured for aqueous electrolyte solutions under a temperature difference and under an osmotic pressure difference. H⁺, Li⁺, Na⁺, K⁺, NH ₄ ⁺ , CH₃NH ₃ ⁺ , (CH₃)₂NH ₂ ⁺ , (CH₃)₃NH⁺, (CH₃)₄N⁺, (C₂H₅)₄N⁺, (n-C₃H₇)₄N⁺ and (n-C₄H₉)₄N⁺ were used as counterions. Water flux across the membrane in HCl solution is higher than that in the other electrolyte solutions because hydrogen ions can exchange with the hydrogen of the neighbor water molecules and contribute to the water transport across the membrane as a proton jump in conductivity. The direction of thermoosmosis across the membrane in HCl, NaCl, (CH₃)₄NCl and (C₂H₅)₄NCl solutions was from the cold side to the hot side and that in LiCl, KCl, NH₄Cl, CH₃NH₃Cl, (CH₃)₂NH₂Cl and (n-C₄H₉)₄NBr solutions was from the hot side to the cold side, although thermoosmosis across anion-exchange membranes always occurs toward the hot side.     

Preparation and characterization of perfluorosulfonic resin/titania hybrid transparent films

Preparation and characterization of perfluorosulfonic resin/titania organic-inorganic hybrid films were presented. The transparent hybrid films were prepared by hydrothermal treatment at low temperature of a mixed solution of tetrabutyl titanate and perfluorosulfonic resin with the help of acetylacetone. The characterization was carried out by SEM,XRD,FT-IR,UV-Vis and TGA. The results showed that the perfluorosulfonic resin/titania hybrid transparent films were composed of titania particles dispersed in the perfluorosulfonic resin matrix very well and the titania was of anatase phase. Its diameter de-creased with increasing weight ratio of titania to perfluorosulfonic resin.     

Nonisothermal membrane phenomena across perfluorosulfonic acid-type membranes,Flemion S: Part II. Thermal membrane potential and transported entropy of ions

Thermal membrane potentials across the perfluorosulfonic acid-type membrane, Flemion S, were measured for HCl, alkali metal chlorides, and ammonium and methyl ammonium chlorides. The difference between the mean molar transported entropy of the counterions in the membrane and the partial molar entropy of the counterions in the external solution was determined from the experimental data on thermal membrane potential, thermoosmosis and electroosmosis. The sign of the thermal membrane potential in HCl solution varies from positive to negative with the concentration. In HCl and alkali metal chloride solutions, the order of their thermal membrane potentials (–/T) is H⁺>Li⁺=Na⁺>K⁺ which is roughly the inverse of that of the crystallographic radii of the ions. However, the order of their entropy differences is H⁺>Na⁺>K⁺>Li⁺ which is just the inverse of that of their thermoosmotic coefficients (D) or the entropy difference of water in thermoosmosis. For the ammonium and methyl ammonium ion forms, the orders of both –/T and increase with an increasing number of methyl groups: (CH₃)₄N⁺>(CH₃)₃NH⁺>(CH₃)₂NH ₂ ⁺ > CH₃NH ₃ ⁺ >NH ₄ ⁺ , which is also the inverse of that ofD or .     

Development and Characterization of Highly Conducting Nonfluorinated Di and Triblock Copolymers for Polymer Electrolyte Membranes

To achieve stable polymer electrolyte membranes (PEMs) with efficient ionic nano-channels, novel fully aromatic AB or ABA copolymers composed of poly(fluorenyl ether sulfone biphenyl)s (PFESBs) and poly(arylene ether sulfone)s (PAESs) were synthesized via polymerization and post-sulfonation methods, and were explored as fuel cell membranes. The structural analysis of synthesized copolymers and the corresponding membranes were ascertained by gel permeation chromatography (GPC), Fourier transform infrared (FTIR), and ¹H nuclear magnetic resonance (NMR) techniques. Thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) analysis showed that the prepared membranes were thermally stable, so that elevated temperature fuel cell operation would be possible. High hydrophilic and hydrophobic nano-phase separation and obvious ionic aggregate block morphology was observed in both triblock and diblock copolymers in atomic force microscopy (AFM) phase images, which may be highly related to their proton transport ability. A sulfonated AB diblock copolymer membrane with an ion-exchange capacity (IEC) of 2.06 meq g^?1 has a maximum proton conductivity of 184 mS cm^?1, which is higher than that of a perfluorosulfonic acid membrane under the same measurement conditions.     

固体全氟烷基有机超酸的催化应用进展

全氟烷基超酸(磺酸RfSO3H,磺酰亚胺(RfSO2)2NH和磺酰基甲烷(RfSO2)3CH)比普通强酸(RSO3H等)表现出更强的酸性和更优秀的催化活性,固载化能提供高效的绿色催化途径.尤其无机载体SiO2负载固体酸,同时具备有机材料和无机材料的优点,比表面大、热稳定性好、酸位点有效、结构/织构可调可控.本文综述了上...     

Ammonia and carbon dioxide permeability through perfluorosulfonic membranes

Transmembrane transport of ammonia and carbon dioxide through perfluorosulfonic membranes in ionic forms of transition metals was studied in a wide temperature interval. The different patterns of the temperature plots of the permeability coefficient of ammonia were found for different ionic forms of the membrane. An increase in the ammonia permeability with an increase in the moisture contents of the membrane also depends on its ionic form. The effects observed are explained by the different structures of water—ammonia complexes formed with metal ions. The mechanism of transmembrane transport of ammonia through perfluorosulfonic membranes in various ionic forms is discussed.     

Mechanical properties of perfluoro sulfonated acids: The role of temperature and solute activity

Water sorption and mechanical properties of perfluoro sulfonated acids (PFSAs), Aquivion and Nafion, are compared under environmentally controlled conditions from 25 to 120 °C and water activities of 0–0.95. Under dry conditions Nafion and Aquivion have thermal transitions at 60 °C and 95 °C, respectively, where the elastic modulus decreases rapidly with increasing temperature. Below their thermal transition temperatures water sorption plasticizes both PFSAs; the elastic moduli decrease with increasing water activity. Above the thermal transition water sorption stiffens both polymers; increasing the water activity from 0 to 0.01 increases the elastic moduli by a factor >10. Plasticization and stiffening are reversible with changing water activity at constant temperature. The thermal transition in PFSAs is suggested to result from reversible clustering of ionic groups. The higher thermal transition temperature for Aquivion is suggested to reduce the risk of membrane thinning and failure due to creep. © 2013 Wiley Periodicals, Inc. J. Polym. Sci. Part B: Polym. Phys. 2013, 51, 915–925     

Effect of side‐chain length on the electrospinning of perfluorosulfonic acid ionomers

The effect of the side‐chain length (short side chain and long side chain, SSC and LSC, respectively) of perfluorosulfonic acid (PFSA) ionomers on the properties of nanofibers obtained by electrospinning ionomer dispersions in high dielectric constant liquids has been investigated with a view to obtaining electrospun webs as components of fuel cell membranes. Ranges of experimental conditions for electrospinning LSC and SSC PFSAs have been explored, with a scoping of solvents, carrier polymer and PFSA ionomer concentrations, and carrier polymer molecular weight. Under optimal conditions, the electrospun mats derived from SSC and from LSC PFSA show distinct fiber dimensions that arise from the different chain lengths of the respective ionomers. Enhanced interchain interactions in SSC PFSA with low equivalent weight compared to LSC PFSA result in a considerably lower average fiber diameter and a markedly narrower fiber size distribution. The proton conductivity of nanofiber mats of SSC and LSC PFSA with equivalent weights of 830 and 900 g mol^?1, respectively, are 102 and 58 mS cm^?1 at 80°C and 95% relative humidity. © 2012 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2013     

Synthesis and identification of dinitro- and diaminoterephthalic acid

Dinitroterephthalic acid(DNTPA) and diaminoterephthalic acid(DATPA) were prepared in 85%and 75%yields,respectively. These compounds were characterized by using FTIR and ~1HNMR.DATPA can be used as a monomer for the preparation of polyesters and polyamides.