冠醚共缩聚物的合成与性能（Ⅱ）

采用２，６－二羟甲基苯酚类化合物分别与单苯并冠醚（Ｂ１５Ｃ５、Ｂ１８Ｃ６）和二苯并冠醚（２Ｂ１８Ｃ６、２Ｂ２４Ｃ８、２Ｂ３０Ｃ１０）在酸催化下缩聚，合成了不同两个系列冠醚共缩聚物，这些聚合物Ｍ＝１２００－４５００，可溶于氯仿等溶剂，萃取性能和络合选择性均有所提高。作为树脂使用，动态吸附容量为０．０５－０．１５ｍｍｏｌ／ｇ，并有较好的色谱特性。     

冠醚苯酚共缩聚物的合成与性能

由２，６－二羟甲基－４－甲基（或磺酸基）苯酚分别和芳香族冠醚（Ｂ１５Ｃ５、Ｂ１８Ｃ６、ＤＢ１８Ｃ６、ＤＢ２４ｃ８等）在强酸催化剂下缩聚，合成了２个系列冠醚共缩聚物。它们的萃取能力和配合作用均优于相应的单冠醚，并可作为树脂吸附分离多种金属离子，作为配合剂测定钾、钠以及作为气相色谱固定液分离多种有机物。     

二苯并18冠6及二苯并24冠8与六聚钼钨杂多酸超分子配合物的合成与晶体结构

报道了两种超分子配合物［Ｎａ（ＤＢ１８Ｃ６）（ＣＨ＿３ＯＨ）］＿２Ｗ＿４Ｍｏ＿２Ｏ＿（１９）·（ＤＢ１８Ｃ６）·（ＣＨ＿３ＯＨ）（Ⅰ）和［Ｎａ（ＤＢ２４Ｃ８）］＿２Ｗ＿１Ｍｏ＿５Ｏ＿（１９）（Ⅱ）的合成方式，用元素分析、电子能谱、ＩＲ和１ＨＮＭＲ等手段进行了表征，并用Ｘ射线测定了晶体结构。结构分析表明：配合物（Ⅰ）属单斜晶系，空间群为Ｐ２１／ｃ，晶胞参数：α＝１．８６９９（５）ｎｍ，ｂ＝１．９５４３（５）ｎｍ，ｃ＝２．２８０８（６）ｎｍ，β＝１１２．８７°，Ｚ＝４．冠醚与多酸根之间通过Ｎａ＋在ＤＢ１８Ｃ６空腔中的镶嵌和Ｏ—Ｎａ—Ｏ键的桥联结合在一起。超分子配合物（Ⅱ）则为Ｎａ＋与ＤＢ２４Ｃ８作用形成配位阳离子，然后与多酸阴离子静电吸引相结合。不同空腔孔径的冠醚与钼钨杂多酸配位时呈现出分子识别与选择性。     

冠醚萃取苦叶酸钪与配合物的晶体结构研究

研究了苯并１５冠５（Ｂ１５Ｃ５）和二苯并１８冠６（ＤＢ１８Ｃ６）萃取苦味酸钪的萃取平衡。在ｐＨ２～３，用斜率法确定了两种萃合物的组成，并由此计算了它们的表观萃取平衡常数。通过苯并１５冠５苦味酸钪配合物的合成、表征及晶体的结构测定，讨论了萃取机理。     

芳香族化合物在苯并系列冠醚聚硅氧烷固定液上的保留机理

分离测得了不同结构芳香族化合物在单苯并（ＰＳＯ－Ｂ－３－１５Ｃ５或１８Ｃ６）、双苯并（ＰＳＯ－ＤＢ－３－１５Ｃ５）和双苯并双叔丁基（ＰＳＯ－ＤＴＢ－３－１５Ｃ５）取代的１５Ｃ５聚硅氧烷固定液上的保留指数、相对保留值以及１０组异构体的热力学参数──溶解焓△Ｈｓ,溶解摘△Ｓｓ和自由能△Ｇ;研究探讨了冠醚环上不同苯基取代的固定液结构对芳香族位置异构体保留行为的影响;通过热力学参数对不同冠醚柱子选择性的表征,证明了苯并系列冠醚固定液对芳烃位置异构体的良好选择分离,主要取决于冠醚环腔的高电子云密度所产生的定向力和强诱导力以及分子和冠醚环腔的适应程度,特别是空间位阻效应起了重要作用。     

在苯-乙醇介质中生成的羧甲基纤维素取代基分布的研究

以三组份两相液体苯 乙醇 水为介质合成羧甲基纤维素（ＣＭＣ），应用１Ｈ ＮＭＲ谱图分析了ＣＭＣ中羧甲基在葡萄糖单元（ＡＧＵ）的Ｃ２、Ｃ３及Ｃ６位上对羟基的取代分布．结果表明，取代基的分布顺序是Ｃ６＞Ｃ２＞Ｃ３；当取代度（ＤＳ）低于１０时，Ｃ２∶Ｃ３∶Ｃ６近似于１４５∶１∶２１５；ＤＳ高于１０以后，分布趋于相同，通过对ＣＭＣ的Ｘ 衍射分析解释了取代基分布规律．同时研究了苯的影响，证实相同取代度下，在苯 乙醇 水中生成的ＣＭＣ试样，其Ｃ６位取代基分布多于在乙醇 水中生成的试样．     

杂元素冠醚研究（Ⅻ）——氧,硫,硒和碲杂冠醚的液膜迁移性能…

报道了碲杂冠醚（ＴｅＢ１５Ｃ５）对Ｎａ＾＋、Ｋ＾＋、Ａｇ＾＋和Ｐｂ＾２＋的液膜迁移能力，并与相应的全氧冠醚（Ｂ１５Ｃ５）、硫杂冠醚（ＳＢ１５Ｃ５）和硒杂冠醚（ＳｅＢ１５Ｃ５）作了比较；同时以ＳｅＢ１５Ｃ５对Ｋ＾＋的迁移为例考察了冠醚浓度和盐浓度对迁移速率的影响。     

二苯并18－冠－6辅助钡离子在1，2－二氯乙烷／水微界面转移的伏安研究

应用液／液界面微电极对二苯并１８－冠－６（ＤＢ１８－Ｃ－６）辅助推动Ｂａ~（２＋）在１，２－二氯乙烷／水（ＤＣＥ／Ｗ）界面转移的电化学过程进行了详细探讨，证明该过程遵循ＴＩＣ机理，是受扩散控制的可逆过程。通过转移电流和反应物浓度之间的线性关系，测定了Ｂａ~（２＋）以及用其它方法难以测定的ＤＢ１８－Ｃ－６。     

3－氨甲基吡啶树脂的合成及五种氨基吡啶树脂对金铂吸附性的比较

研究了反应物配料比３－ＡＭＰ／Ｃｌ（摩尔比）、反应温度与时间对大孔型３－氨甲基吡啶树脂（３—ＡＭＰＲ）性能的影响规律．在最佳合成工艺条件下制得３－ＡＭＰＲ的功能基含量为３．１６ｍｍｏｌ／ｇ树脂．３－ＡＭＰＲ对ＡｕＣｌ６（２－），ＰｔＣｌ６（２－），ＩｒＣｌ６（２－），ＰｄＣｌ４（２－），ＲｈＣｌ６（３－）的吸附容量分别为８００．８，３８７．８，３８６．３，１３３．０，１０５．５ｍｇ金属／ｇ树脂；配位比分别为１．２９，０．６３，０．６４，０．４０，０．３３。比较了３—ＡＭＰＲ、２－ＡＭＰＲ、４－氨基吡啶树脂（４－ＡＰＫ）、３—ＡＰＲ、２－ＡＰＲ五种树脂对ＡｕＣｌ４－、ＰｔＣｌ６（２－）的吸附性，其中３－ＡＭＰＲ为最佳。     

温度和压力对六氟二酐型聚酰亚胺的透气性能的影响

本文研究了温度和压力对五种六氟二酐（６ＦＤＡ）型聚酰亚胺膜对Ｈ_２、ＣＯ_２、Ｏ_２、Ｎ_２和ＣＨ_４五种气体透过性能的影响．在３０－１００℃区间，五种聚酰亚胺的透气系数与温度的关系均符合Ａｒｒｈｅｎｉｕｓ关系式；在０．３－１．２ＭＰａ区间，压力对透气系数的影响很小．６ＦＤＡ－４，４＇－二氨基二苯酮（ＤＡＢＰ）和６ＦＤＡ－３，３＇－二甲基二苯甲烷二胺（ＤＭＭＤＡ）在１００℃仍然具有较大的透气选择系数，是比较好的气体分离膜材料．     

酚醛冠醚共缩聚物的合成与性能

用2,6-二羟甲基-4-苯基苯酚分别与二苯并-18-冠-6(2B18C6)、二苯并-24-冠-8(2B24C8)、二苯并-30冠-10(2B30C10)、苯并-15-冠-5(B15C5)、苯并-18-冠-6(B18C6)缩聚合成了五种酚醛型冠醚共聚物。我们用聚冠醚的氯仿溶液萃取苦味酸碱金属盐水溶液,研究了它们对金属离子的络合性能。结果表明,聚冠醚(PB15C5)和(PB18C6)的萃取能力和选择性显著优于相应的单冠醚。     

冠醚共缩聚物的合成与性能

双冠醚化合物对某些金属离子比单冠醚具有更好的络合性能和选择性,它们合成、应用研究越来越受到人们的重视,本工作采用2,6-二羟甲基对甲氧基苯酚为缩合剂与芳香族冠醚缩聚,得到一系列具有双冠醚结构特征的新酚醛型聚苯并冠醚(简称聚冠醚),聚冠醚合成容易,并呈现了比相应单冠醚更优越的络合萃取能力和富集效率。     

Ion-pair extraction of tetravalent plutonium from hydrochloric acid medium using crown ethers

Ion-pair extraction behaviour of plutonium (IV) from varying concentrations of HCl solution was studied employing crown ethers (benzo-l5-crown-5 (B15C5), 18-crown-6, (18C6), dibenzo-18-crown-6 (DB18C6), dicyclohexano-18-crown-6, (DC18C6), dibenzo-24-crown-8 (DB24C8) and dicyclohexano-24-crown-8 (DCH24C8)) in nitrobenzene as the extractant. Ammonium metavanidate was used as the holding oxidant in the aqueous phase and the conditions necessary for the quantitative extraction of the tetravalent ion were found. The co-extraction of species of the type [HL⁺].[HPu(Cl) ₆ ^– ] and [HL⁺]2·[Pu(Cl) ₆ ^2– ] as ion-pairs (where L represents the crown ether) is suggested.     

Thermodynamics of Amino Acid Methyl Ester Hydrochlorides—Crown Ether Complexes in Methanol at 25°C

Stability constants, free energies, and enthalpies and entropies of the complexation of L-alanine methyl ester hydrochloride (L-Ala-HCl), L-phenylalanine methyl ester hydrochloride (L-Phe-HCl), and valine methyl ester hydrochloride (L-Val-HCl) with 15-crown-5 (15C5), benzo-15-crown-5 (B15C5), 18-crown-6 (18C6), benzo-18-crown-6 (B18C6), dicyclohexano-18-crown-6 (DC18C6), and dicyclohexano-24-crown-8 (DC24C8) in methanol are reported for 20°C. No significant variation in the stability constants and free energies of complexation is observed, indicating that the various crown ethers are poorly selective in binding the amino acids. However, the nature of the crown ether and the amino acid and their pattern of substitution cause a remarkable variation in the enthalpies and entropies of complexation. This indicates a strong enthalpy–entropy compensation effect. The enthalpy–entropy compensation effect for the crown ether complexes of the amino acid methyl ester hydrochlorides reported herein is compared with that of the crown ethers complexes of the amino alcohols and the free amino acid. It is found that the enthalpy–entropy compensation effect holds equally for the three classes of complexes.     

Crown ether molecular complexes with urea and thiourea

Crystalline complexes of urea and thiourea with crown ethers, have been prepared, viz., 18-crown-6 (18C6), benzo-18-crown-6 (B18C6), dibenzo-18-crown-6 (DB18C6), dicyclohexano-18-crown-6 (DC 18C6) and dibenzo-24-crown-8 (DB24C8). While the complexes of the large ring size crown ether, DB24C8, have high ether to (thio)urea ratios, the stoichiometry of the others lies between one molecule of crown ether and from one to six molecules of (thio)urea. An IR spectral study of the urea and thiourea complexes showed that the behavior of thiourea in these complexes is clearly different from that of urea, indicating the role of sulphur in the interaction of thiourea with crown ethers. The urea and thiourea complexes were classified according to their stoichiometries and their IR spectral behavior into three classes for which credible structures were proposed.     

Crystal Structure and Properties of a New Copper(II) Complex of Dioxocyclam Appended with 8-Methylquinoline (Dioxocyclam = 1,4,8,11-tetraazacyclotetradecane-5,7-dione)

The IR spectra of the crystalline complexes of 3-and 4-nitrophenol with crown ethers were studied, viz.,18-crown-6 (18C6), benzo-18-crown-6 (B18C6),dibenzo-18-crown-6 (DB18C6), dicyclohexano-18-crown-6 (DC18C6) and dibenzo-24-crown-8 (DB24C8). The spectra of uncomplexed crown ethers showed water absorption bands which indicate the presence of two types of bound water molecules, viz., cavitant water enclosed by the strong ether-cavity field and outer-layer hydrogen-bonded water molecules. Upon complexation with 3- and 4-nitrophenol, the bands attributed to cavitant water disappeared, leaving the outer layer water to act as a bridge between the host crown ether and the guest phenols. The results further showed that of the crown ethers and of the phenols, B18C6 and DC18C6 and 3-nitrophenol, have the strongest interaction. The behaviour of the phenols was explained by the increased contribution of the inductive-moment over the resonance -moment in thecomplexes.     

Perfluoroalkylation of benzo crown ethers with sodium perfluoroalkanesulfinates in the presence of oxidant

Using Ce(SO4)2 or Mn(OAc)3 as oxidant, dibenzo crown ethers such as dibenzo-18-crown-6 (1) and dibenzo-24-crown-8 (5) and benzo-12-crown-4 (7) reacted smoothly with sodium perfluoroalkanesulfinates (2a-2e) to give the corresponding perfluoroalkylated products (3,4,6,7) in good yields with two isomers obtained in the case of dibenzo crown ethers. This provides a facile synthesis of perfluoroalkyl-containing crown ethers.     

Theoretical investigation of the complexation of crown ethers and crown ethers of fulleropyrrolidine with (CH3)(x)NH+(4-x), x = 0-4

The electronic and geometric structures of dibenzo-12-crown-4, dibenzo-18-crown-6, and dibenzo-24-crown-8 ethers, and dibenzo-18-crown-6 ether of fullero-N-methylpyrrolidine and their complexes with (CH(3))(x)NH+(4-x), x = 0-4 were investigated by employing density functional theory (B3LYP, M05-2X, M06-2X, MPWBIK and B2PLYP-D) in conjunction with three basis sets. Different energetic minima have been identified for all of the above molecules and complexes in the gas phase as well as in CHCl(3) solvent. We report geometries, complexation energies and some thermochemical data. For increasing values of x, the complexation energies, corrected for the basis set superposition error range from 3.29 to 0.73 eV in the gas phase and from 1.56 to 0.13 eV in the CHCl(3) solvent. In the case of the largest crown ethers, the 24-crown-8 ethers are folded around the ammonium cation so as to maximize the number of hydrogen bonds formed and present the largest complexation energies. Finally, the presence of fullero-N-methylpyrrolidine, attached to the crown ethers, does not change the complexation energies substantially.     

Allylation of phenoxides by crown ethers and their polymers

Allylation of sodium phenoxide in the presence of crown ethers produces a high ratio of O/O + C allylation when conducted in water, phenol, benzene, or diethyl ether. The striking increase in the product ratios is attributed to specific complexation of the crown ethers that facilitate the dissociation of the ion pair aggregate of the sodioderivative in benzene or diethyl ether. The crown ethers may act as a phase transfer catalyst when the reaction is run in water. Furthermore, the O/O + C ratios of the allylation strongly depend on the kind of crown ethers used. To examine their effect the allylation of sodium phenoxide was studied with various crown ethers, such as 18-crown-6, benzo-18-crown-6, benzo-15-crown-5, poly(vinylmonobenzo-15-crown-5), and poly(vinylmono-benzo-18-crown-6), as catalysts. It was found that among these crown ethers poly(vinylmono-benzo-15-crown-5) was the most effective catalyst.