二氧化碳与不饱和烃的还原羧化反应

过渡金属催化CO₂参与的不饱和烃还原羧化反应是合成羧酸及丙烯酸类化合物的重要途径, 具有重要的研究价值和工业应用潜力．过渡金属试剂与不饱和烃、CO₂生成稳定的金属杂环内酯或金属羧酸盐．还原剂能够与金属杂环内酯或金属羧酸盐发生转金属作用, 重新生成活泼催化剂, 从而实现催化剂的循环利用．本文总结了还原剂, 包括有机金属试剂、硅烷、硼烷、金属粉末、甲醇和氢气等在不饱和烃与CO₂的还原羧化反应中的应用, 并着重描述其反应特点和反应机理.     

N-羧丙酰壳聚糖钠增强改性壳聚糖棒材

采用原位沉析法制备N-羧丙酰壳聚糖钠增强改性的三维壳聚糖复合棒材, 并用傅里叶变换红外(FTIR)光谱、X射线衍射(XRD)、热重(TG)分析、扫描电镜(SEM)以及力学性能测试等方法研究复合棒材结构与性能之间的关系. FTIR分析表明, 壳聚糖分子中的氨基官能团和乙酰氨基官能团均与N-羧丙酰壳聚糖钠分子中的羧酸盐官能团发生强烈的静电相互作用. 加入N-羧丙酰壳聚糖钠后: 两种分子间产生强烈的静电相互作用, 限制了大分子链的运动, 使得大分子链趋于刚性, 同时复合棒材的层状叠加结构变得更加紧密, 提高了复合棒材的热稳定性与力学性能; 大分子链的刚性增强, 限制了分子链排入晶格, 从而降低了壳聚糖的结晶度. 当复合棒材中含有15% (w)的N-羧丙酰壳聚糖钠时, 其弯曲强度和弯曲模量可达156.0 MPa、5.3 GPa, 与纯壳聚糖棒材相比, 分别提高了68.8%、29.3%.因此, N-羧丙酰壳聚糖钠可有效地增强改性三维壳聚糖棒材, 该三维复合物棒材有望用作骨折内固定材料.     

DSB显著提高羧酸盐驱油体系抗钙镁离子能力的研究

测定了工业品级的天然混合长链烷基羧酸盐(SDC)以及与3-(N,N-二甲基十二烷基胺)-2-羟基-丙磺酸(DSB)复配驱油体系的界面张力(ITFmin), 分别得出其抗钙镁离子的能力为400和5000 mg/L. 选择试剂级十二烷基羧酸钠与DSB复配, 测定了不同配比溶液的表面张力值和临界胶束浓度cmc, 结合长链烷基脂肪酸与钙离子的溶度积Ksp, 分析了对不溶性长链烷基羧酸盐形成的影响. 根据现场驱油体系配方, 计算了两者在溶液中的摩尔配比为4:1时的十二烷基羧酸盐在胶束中的摩尔分数xm1为0.51, 相互作用参数βm值为-3.11, 反映了两者有较强的相互作用. 采用量子化学方法, 对由1个十二烷基羧酸分子、1个DSB分子及1个二价钙离子组成的模型复合物进行了能量计算和电荷分布计算, 得出在长链烷基羧酸盐和DSB两者混合胶束的界面层中存在负电荷空穴, 提出二价金属离子被络合的模型, 合理地解释了实验事实.     

水溶性壳聚糖降血脂作用的化学机理(Ⅰ)──水溶性壳聚糖及其衍生物对胆酸盐的结合能力研究

通过壳聚糖氧化裂解,制备了分子量为8000的水溶性壳聚糖,并通过烷基化反应合成了二乙氨乙基壳聚糖、二甲氨基(1-甲基)乙基壳聚糖及二乙基甲基铵乙基壳聚糖.在体外测定了水溶性壳聚糖及其衍生物对胆酸盐(牛磺胆酸钠和甘氨胆酸钠)的结合能力及其影响因素.结果表明,水溶性壳聚糖结合胆酸盐的能力主要取决于其阳离子化程度.修饰后的壳聚糖结合胆酸盐的能力增强,说明引入更多的胺基或铵基有利于对胆酸盐的结合.     

含胺基功能性单体的聚合研究——ⅩⅦ.N-(4-二甲氨基苯基)马来酰亚胺的聚合及其光化学行为

关于在同一分子中既含有给电子生色基团又含有受电子碳碳双键基的单体的合成、聚合及它们的光化学行为,我们所报道过的多是一元不饱和羧酸的衍生物。本文报道含有给电子生色基因的1,2-不饱和二元羧酸类单体N-(4-二甲氨基苯基)马来酰亚胺(DMAPMI)的合成、聚合及其光化学行为。     

凝胶体系中不同结构羧酸盐对草酸钙生物矿化的影响

采用双扩散法研究了凝胶体系中四元羧酸盐(Na2EDTA)、三元羧酸盐柠檬酸钠（Na3cit）、二元羧酸盐酒石酸钠（Na2tart）和一元羧酸盐醋酸钠（NaAc）对草酸钙（CaOx）结晶的影响.抑制一水草酸钙（COM）聚集的能力为:Na2EDTA >Na3cit >Na2tart >NaAc；诱导二水草酸钙（COD）的能力为：Na3cit >Na2tart >Na2EDTA >NaAc.羧酸的抗衡阳离子影响CaOx的结晶. H3cit、Na3cit和K3cit抑制COM聚集和诱导COD形成的能力均为:K3cit-Na3cit >H3cit.无论是诱导COD生成，还是抑制COM聚集，均可以减小结石形成的几率，对临床上防治结石具有积极的意义.     

藏红T分光光度法测定醇醚羧酸盐初级生物降解率

以碱性藏红T溶液作为指示剂,在pH8.6的硼酸-硼砂缓冲溶液中,三氯甲烷为萃取剂,采用紫外可见分光光度法对醇醚羧酸盐(AEC)进行了研究。结果表明:无表面活性的磷酸盐、乙酸盐以及常用的Cl~-、HCO_3~-和SO_4~(2-)对体系无影响,而具有表面活性的十二烷基硫酸钠和烷基苯磺酸钠对体系具有明显的影响,导致吸光度增大。方法检出限(3s)为0.2mg·L~(-1)。对醇醚羧酸盐的初级生物降解研究表明,即使醇醚羧酸盐(含有9个乙氧基)的质量浓度为100mg·L~(-1)时,24h的降解度达到95%以上;醇醚羧酸盐具有好的生物降解性能,在自然条件下能完全生物降解。     

草酸钙的结晶动力学及不同种类羧酸盐的影响

通过检测体系中游离Ca2+离子浓度及草酸钙(CaOxa)的粒径随时间的变化,研究了CaOxa的结晶动力学及3种羧酸盐对CaOxa结晶动力学的影响,这些羧酸盐为:一元羧酸盐甘氨酸钠(NaGlu)、二元羧酸盐酒石酸钠(Na2Tart)和三元羧酸盐柠檬酸三钠(Na3Cit)。在生理盐水中CaOxa的结晶动力学方程为r=kc3.3±0.3,平均反应速率常数(k)为(3.1±1.8)×109;3种抑制剂对k的影响程度从大到小为:Na3Cit>Na2Tart>NaGlu,但其平均反应级数(α)相差不大,α=3.2±0.1。Na3Cit、Na2Tart可抑制CaOxa晶体的生长和聚集过程,是潜在的肾结石抑制剂。     

碳氟型及碳氫型乳化剂对苯乙烯及α,β,β-三氟苯乙烯乳液聚合速度的影响

用膨胀计法研究了在不同乳化剂存在下,苯乙烯及α,β,β-三氟苯乙烯的乳液聚合速 度,所用的乳化剂是:碳氟链型乳化剂H(CF_2)_nCOOK,n=6,8,10,和CF_2Cl(CFClCF_2)_3COOK及碳氢链型乳化剂H(CH_2)_nCOOK,n=8,11。在所有情况下,α,β,β-三氟苯乙烯的聚合速度都低于苯乙烯。用碳氢链羧酸盐作乳化剂时,苯乙烯与α,β,β-三氟苯乙烯的聚合速度大于用碳氟链羧酸盐作乳化剂时的聚合速度,在ω-氢全氟羧酸钾系列中,H(CF_2)_nCOOK,n=6,8,10,用n=8的羧酸钾作乳化剂时单体的聚合速度最大。     

聚羧酸盐分散剂在农药水悬浮剂中的应用及作用机理分析

聚羧酸盐分散剂具有独特的分散性能,可显著提高农药水悬浮剂等剂型的稳定性.本文应用3种聚羧酸盐分散剂分别制备了3种农药水悬浮剂,研究了聚羧酸盐分散剂在原药颗粒表面的吸附特征和吸附热力学,研究了聚羧酸盐分散剂对农药水悬浮体系Zeta电势和流变性质的影响,并分析了体系在热贮前后各稳定性参数的变化,最终得到了具有长期储存稳定性的农药水悬浮剂产品.研究结果显示,聚羧酸盐分散剂在原药颗粒表面的吸附符合Langmuir单分子层吸附模型,其中吸附热力学参数?G_(ad)0、?S_(ad)0、?H_(ad)0且|?H_(ad)|40 kJ mol~(-1),表明该吸附为自发进行的、放热、熵增的物理吸附过程.聚羧酸盐分散剂通过提高悬浮体系的Zeta电势,使得分散粒子间相互排斥,改善了体系的流动性能,从而提高农药水悬浮剂产品的长期储存稳定性.     

Crystalline Transformation of Chitosan from Hydrated to Anhydrous Polymorph Via Chitosan Monocarboxylic Acid Salts

ABSTRACT

Spontaneous removal of monocarboxylic (formic, acetic, propionic or butyric) acids accompanying dehydration of the corresponding chitosan salts was observed from X-ray fiber diffraction diagrams obtained during the storage of these salts for a given period of time. The first three salts were prepared by immersing a tendon chitosan (a hydrated crystal) in an aqueous solution of respective monocarboxylic acid and 2-propanol. The salts showed similar fiber patterns not only to one another but also to the “Eight-fold” polymorph of the original chitosan, indicating that they are Type II salts, hydrated crystals, where the backbone chitosan molecule takes up an eight-fold helical conformation. The temperature required for the salt formation depended on the hydrophobicity of the acid, e.g., the chitosan formic acid salt could be prepared at room temperature, whereas, formation of the propionic acid salt was carried out at 4 °C. All the acids spontaneously evaporated accompanied by dehydration during storage of the salts, resulting in formation of anhydrous crystalline chitosan. Removal of the monocarboxylic acids was accelerated by increasing the hydrophobicity of the acid: at 100% relative humidity approximately 3 months for the formic, 1 month for the acetic and 3 weeks for the propionic acid salts. In the case of butyric acid the anhydrous polymorph of chitosan was obtained immediately after the reaction, suggesting that the water removing action of this acid was too fast to detect a Type II salt by the present X-ray method. The anhydrous crystals of chitosan were irreversibly prepared by annealing a hydrated crystal in water at a high temperature, such as 240 °C, leading to a little loss of orientation and to thermal decomposition of the sample specimen to some extent. But it was found that, through Type II salts of monocarboxylic acids, the hydrated crystals of chitosan can be dehydrated even at room temperature without any loss of orientation and decomposition of the chitosan specimen.     

N-乙基壳聚糖的针状结晶

在N 乙基壳聚糖的甲酸溶液浇铸膜中观察到高分子少有的针状晶体 .从球晶经后结晶得到的针状晶体为长条矩形 ,典型尺寸为～ 5 0 μm× 2～ 5 μm× 1～ 2 μm ,高分子链平行于晶体长轴 .针状晶体首先出现在球晶的核心处 ,继而出现在球晶微纤每个树枝状分叉处 ,最后才遍布球晶各处 .针状晶体可以看成是高分子伸直链结晶的一种 .浇铸膜吸潮实际上形成了超浓溶液 (浓度 >80wt% ) ,从而分子链可以运动而后结晶成针状晶体     

Selective crystallization of calcium salts by poly(acrylate)-grafted chitosan

The biopolymer chitosan was chemically modified by grafting polyacrylamide or polyacrylic acid in a homogeneous aqueous phase using potassium persulfate (KPS) as redox initiator system in the presence of N,N-methylene-bis-acrylamide as a crosslinking agent. The influence of the grafted chitosan on calcium salts crystallization in vitro was studied using the sitting-drop method. By using polyacrylamide grafted chitosan as substrate, rosette-like CaSO4 crystals were observed. This was originated by the presence of sulfate coming from the initiator KPS. By comparing crystallization on pure chitosan and on grafted chitosan, a dramatic influence of the grafted polymer on the crystalline habit of both salts was observed. Substrates prepared by combining sulfate with chitosan or sulfate with polyacrylamide did not produce similar CaSO4 morphologies. Moreover, small spheres or donut-shaped CaCO3 crystals on polyacrylic acid grafted chitosan were generated. The particular morphology of CaCO3 crystals depends also on other synthetic parameters such as the molecular weight of the chitosan sample and the KPS concentration.     

羧酸盐类成核剂在聚2,6-萘二甲酸乙二酯中的化学成核

采用与PEN分子结构单元相似的 2 ,6 萘二甲酸二甲酯 (DMN)和熔点较低的邻氯苯甲酸钠 (SOCB)为模型化合物 ,用DSC、FTIR、带热台偏光显微镜 (HPOM)和HPLC等方法 ,研究了DMN和SOCB在热处理过程中的化学反应 .DSC和HPOM研究也证明了PEN与SOCB在高温下发生化学反应 .因而提出羧酸盐类成核剂在PEN中的成核是“化学成核” .即在高温下羧酸盐类成核剂和PEN发生化学反应 ,生成PEN的羧端基离子盐 ,该离子盐是真正的成核剂 ,起到成核作用     

Degradation of crosslinked unsaturated polyesters in sub-critical water

The degradation of unsaturated polyesters crosslinked with styrene was performed in sub-critical water (SCW) in the absence and presence of organic additives. The unsaturated polyesters were de-crosslinked by hydrolysis of ester chains to form polystyrene derivatives on SCW treatment at 300 °C. With an increase in treating time, carboxylic acid groups in the polystyrene derivatives were turned into carboxylic anhydride groups in SCW. The de-crosslinking rate was much enhanced on SCW treatment in the presence of hydroxy compounds with a long alkyl chain and alkylamines, while carboxylic acids, benzenesulfonate salts, and quaternary ammonium salts were ineffective even though they had a long alkyl chain. The degree of de-crosslinking was reduced in the presence of diamines and amino acids because re-crosslinking at both ends of the additive molecules proceeded.     

粘度法研究壳聚糖对外加盐的敏感性

聚电解质的特性粘度对外加盐的响应是反映聚电解质对外加盐敏感性的一个重要特征，通过分别测定壳聚糖在不同小分子强电解质（ＮａＣｌ、ＫＣｌ、ＣａＣｌ２、ＢａＣｌ２）和相同小分子强电解质（ＮａＣｌ）但不同离子强度的稀溶液粘度，得到：（１）壳聚糖特性粘度与外加盐的离子强度的平方根的倒数成正比；（２）不同小分子强电解质中阳离子对壳聚糖特性粘度的影响次序是Ｎａ＋＞Ｋ＋＞Ｂａ２＋＞Ｃａ２＋．同时，测算了壳聚糖在不同外加盐浓度中的Ｍａｒｋ Ｈｏｕｗｉｎｋ方程参数α，发现其值皆大于０５，得到了壳聚糖分子链的僵硬性参数Ｂ的值为００７４，揭示了壳聚糖具有较大的分子链刚性和抗盐性能．     

Crystallization of bisphenol-A polycarbonate induced by organic salts; physical aspects. I. Crystallization rate,melting behavior,and morphology

The presence of organic acid salts in bisphenol-A polycarbonate (PC) completely modifies the crystallization mechanism, the melting behavior, and the morphology of the polymer. Organic salts are not ordinary nucleating agents for PC since they react with the polymer, producing metal phenoxide chain ends. On reaction, abundant instaneous nucleation is induced. The seeds are likely to be polymer crystalline fragments preexisting in the melt. The phenoxide chain ends significantly increase the growth rate of the crystalline phase. Melting points and enthalpies of fusion are unusually high, suggesting a high degree of crystalline perfection. Thick multilamellar crystals, which are likely to contain chains in extended configuration, are observed by electron microscopy. No trace of spherulitic morphology is found. The chemical instability of PC containing ionic chain ends is also shown to seriously affect the crystallization rate, the maximum degree of crystallinity, and the melting point.     

Micropore to macropore structure-designed silicas with regulated condensation of silicic acid nanoparticles

A new preparation method for porous silica particles was developed using activated silica sols which are called nano-silica solutions in this paper. Several kinds of organic and inorganic acids are employed to neutralize diluted sodium silicate solutions to form the nano-silica solutions: formic acid, acetic acid, propionic acid, oxalic acid, succinic acid, dl-malic acid, citric acid, and tricarballylic acid as carboxylic acids, and sulfuric acid and hydrochloric acid as inorganic acids. The effect of salts in the nano-silica solution is also studied. The products were investigated using a field emission scanning electron microscope, an X-ray diffractometer, the nitrogen adsorption technique, and a mercury porosimeter. Microporous silicas were produced when carboxylic acids were applied; the formation of micropores was influenced by the pH of the nano-silica solutions and molecular sizes of the carboxylic acids. Addition of a salt in a citric acid solution increased the mesopore volume. Macropores were formed when inorganic acids including salts were applied; the salt nanoparticles which were crystallized in silica spheres acted as templates. The anion types and salt concentrations in the nano-silica solutions affected the aggregation condition of silica nanoparticles, following the Schulze-Hardy rule.     

Crystallization behavior of poly(ε‐caprolactone)/multiwalled carbon nanotube composites

Differential scanning calorimetry (DSC), polarized optical microscopy, and X‐ray diffraction methods were used to investigate the isothermal crystallization behavior and crystalline structure of poly(?‐caprolactone) (PCL)/multiwalled carbon nanotube (MWNT) composites. PCL/MWNT composites were prepared via the mixing of a PCL polymer solution with carboxylic groups containing multiwalled carbon nanotubes (c‐MWNTs). Both Raman and Fourier transform infrared spectra indicated that carboxylic acid groups formed at both ends and on the sidewalls of the MWNTs. A transmission electron microscopy micrograph showed that c‐MWNTs were well separated and uniformly distributed in the PCL matrix. DSC isothermal results revealed that introducing c‐MWNTs into the PCL structure caused strongly heterogeneous nucleation induced by a change in the crystal growth process. The activation energy of PCL drastically decreased with the presence of 0.25 wt % c‐MWNT in PCL/c‐MWNT composites and then increased with increasing MWNT content. The result indicated that the addition of c‐MWNT to PCL induced heterogeneous nucleation (lower total activation energy) at a lower c‐MWNT content and then reduced the transportation ability of polymer chains during crystallization processes at a higher MWNT content (higher total activation energy). A correlation between the crystallization kinetics, melting behavior, and crystalline structure of PCL/c‐MWNT composites was also discussed. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 44: 598–606, 2006     

Branched Crystalline Patterns Formed Around Poly(ethylene oxide) Dots in Humidity

Branched patterns reminiscent of diffusion‐limited aggregation form around poly(ethylene oxide) dots on Au surfaces in humidity by crystallization of polymer chains in water‐assisted diffusion, involving fractal‐like structure and dense branching‐like morphology (DBM). Higher humidity leads to a slower growth of crystal lamellae. Crystal growth promotes outward diffusion. Fractal‐like lamellae are viewed flat‐on. Due to the reduction of chain availability in the diffusion field, the fractal‐like structure turns into DBM.