铯助合成对称-双-[4,4′(5′)-叔丁基一二苯并]-21-冠-7

Kellogg 和 Reinhoudt 各自独立地报道了用铯助合成方法制备芳并冠醚,例如,由邻苯二酚和缩甘醇对甲苯磺酸酯与氟化铯,或由邻苯二酚和缩甘醇二溴化物与碳酸铯反应,以     

NMR和XAFS方法研究溶液中杯芳冠醚与碱金属离子配位化学

给出了1,3-二辛氧基杯[4]芳烃冠醚-6(25,27-bis-octyloxy-calix[4]arene-26,28-crown-6, BOC6)和杯[4]芳烃双冠醚-6(1,3-alternate biscrown-6, BisC6)晶体结构参数, 用NMR(CDCl₃作溶剂)和XAFS(X-ray absorption fine structure)方法研究了邻硝基苯甲醚(o-nitro-phenyl methyl ether, NPME)和正辛醇(n-octyl alcohol, OA)溶液中BOC6和BisC6与碱金属离子的配位行为. 结果表明: 铯离子的嵌入使得杯芳冠醚分子中冠醚链的对称性明显提高; 在溶液中,配合物分子中铯离子的配位数为7, 7个氧的配位是一种稳定结构.     

大环杯芳烃冠醚的研究现状与展望

杯芳冠醚是杯芳烃化学中最令人瞩目的研究热点之一。本文综述了大环杯[5，6，8]芳冠醚的合成、构象固定、衍生化以及它们的识别性能等方面的研究进展。并对其发展前景作了展望。参考文献25篇。     

基于多重氢键组装的双杯冠合成及对铯离子的络合

合成了一种基于多重氧键组装形成的新型双杯冠化合物,利用核磁共振氢谱(1H NMR)和碳谱(13C NMR)以及高分辨质谱(ESI-HRMS)对组装前体分子结构进行了表征.通过一维和二维核磁共振氢谱(2D NOESY)研究了该双杯冠的的自组装结构,并采用核磁共振和紫外-可见光谱的方法测定了其对铯离子的络合.实验表明,通过氢键组装形成的双杯冠化合物,由于阻止了单杯冠分子内组装而限制了冠醚环构象改变,其萃取率由单杯冠的82％提高到96％.     

二苯骈－21－冠－7与12－磷钨酸铯配合物的合成及表征

二苯骈－２１－冠－７与１２－磷钨酸铯配合物的合成及表征陈伟，罗良琼（四川联合大学（东区）化学系成都６１００６４）关键词合成，冠醚配合物，１２－磷钨酸铯二苯骈－２１－冠－７（ＤＢ２１Ｃ７）与含简单阴离子的铯盐配合物已有一些研究［１］，但是ＤＢ２１Ｃ７与...     

铯榴石硫酸浸出提取铯盐工艺研究

简述了铯榴石提铯工艺的概况, 确定了铯榴石硫酸法生产铯盐的工艺, 研究了铯榴石硫酸浸出的主要工艺的条件, 优化选择了硫酸浸出的最佳条件, 为工业化生产提供了可靠的依据.     

提篮型杯[4]芳烃冠醚的合成及其对铯离子络合性能的研究

本文从去叔丁基化的杯[4]芳烃出发,先后分别在1,3-和2,4-酚羟基位点上引入正辛烯基和支链冠醚,最后通过烯烃复分解反应,合成了一种新型的提篮型杯芳烃冠醚化合物,产物结构经过1H NMR和HRMSESI表征确定.分别采用1H NMR和UV-vis方法,研究了1,3-桥联成环后张力对另一端冠醚环络合选择性的影响.结果表...     

杯芳烃衍生聚合物用作毛细管气相色谱固定相的研究

合成了两种不同构象的杯芳烃衍生聚合物（杯芳冠醚聚硅氧烷ｃ－ｃ［４］ｃ５－ｐｓｏ和二乙氧基杯［４］芳烃聚硅氧烷ｐ－ｃ［４］－ｐｓｏ），并将其用作毛细管气相色谱固定液，使用温度高达３２０℃，对不同的极性化合物，特别是对酚类异构体有很好的分离能力。同时也研究了分离机理。     

杯芳烃固定液分子识别的热力学性质

用毛细管气相色谱法测得了５组芳香族位置异构体在杯芳冠醚聚硅氧烷（Ｃ［４］Ｃ５＿ＰＳＯ），二乙氧基杯芳烃聚硅氧烷（Ｃ［４］Ｅ＿ＰＳＯ）和二丁氧基杯芳烃聚硅氧烷（Ｍ＿Ｃ［４］Ｂ＿ＰＳＯ）３种杯芳烃固定液上的热力学参数ΔＨ、ΔＳ、ΔＧ，然后用热力学及超热力学的方法探讨了杯芳烃对异构体的分子识别特性和保留机理。     

离子缔合型离子选择电极的研究——Ⅶ.PVC 膜铯离子选择电极的研制

铯离子选择电极的研制,国外曾报导过四苯硼铯液膜型、冠醚-PVC膜型和非均相固膜型等类型。四苯硼铯-PVC膜艳电极未见报导。本文在离子缔合型阴离子选择电极研究的基础上,报道了一种以四苯硼铯为活性物质的离子缔合型阳离子选择电极——PVC膜铯离子电极的研制。电极对铯离子的线性响应下限为4×10~(-5)M,斜率为50mV/pCs(28℃);若在以四苯硼艳饱和的1×10~(-2)M氯化铯中将电极活化12小时以上,并保存于此溶液中,则电极响应斜率可提高到55mV/pCs(17℃),但线性响应下限升高至1×10~(-4)M。电板寿命在三个月以上。     

A PGSE diffusion and electrophoretic NMR study of Cs+ and Na+ dynamics in aqueous crown ether systems

Multinuclear pulsed gradient spin-echo (PGSE) NMR diffusion and linewidth measurements were used to probe binding and transport in aqueous Na+-15-crown-5, Na+-18-crown-6, Cs+-15-crown-5 and Cs+-18-crown-6 systems. Since direct PGSE observation of many alkali cations is precluded by either low inherent sensitivity or rapid relaxation (or both), the feasibility of proton-detected electrophoretic NMR (ENMR) measurements to complement PGSE data was investigated. ENMR measurements were performed on aqueous Cs+-, Li+-, Na+-, K+-, and Rb+- 18-crown-6 systems. The data analysis is based on a two-site binding model and its corresponding association constants. Cs+ was found to bind considerably more tightly to 18-crown-6 (K=8 M-1) than to 15-crown-5 (K approximately 2 M-1), whereas Na+ had almost equal affinity (K approximately 4.5 M-1) for 15-crown-5 and 18-crown-6. The difficulties encountered in analysing the NMR parameters, methodological limitations and the implied need for more complicated binding models are discussed.     

Cs1-xSn1-xBi9+Se15 and Cs1.5-3xBi9.5+xSe15: members of the homologous superseries Am[M1+lSe2+l]2m[M1 + 2l+nSe3 + 3l+n] (A = alkali metal,M = Sn and Bi) allowing structural evolution in three different dimensions

Cs1-xSn1-xBi9+xSe15 and Cs1.5-3xBi9.5+xSe15 crystallize in a new structure type which does not belong to but is closely related to the members of the homologous series Am[M6-Se8]m[M5+nSe9+n]; the new phases reveal a third dimension of structural evolution for this series according to the formula Am[M1+lSe2+l]2m[M1 + 2l + nSe3 + 3l+n].     

An anomalous x-ray diffraction study of the hydration structures of Cs+ and I- in concentrated solutions

Anomalous x-ray diffraction experiments were carried out on concentrated aqueous solutions of sodium iodide (6 molal) and cesium iodide (3 molal). Data were gathered at two energies below the absorption edges of the Cs+ and I- ions in order to avoid contributions from fluorescence. The statistics and quality of the raw data were improved by the use of a focusing analyzer crystal. Differences were taken between the data sets and used to calculate the hydration structures of Cs+ and I-. The structures found are more complex than anticipated for such large ions with relatively low charge densities and show evidence of ion-pair formation in both solutions. A two-Gaussian fit to the Cs+ data gives information about the Cs+-O and Cs+-I- correlations. The central position of the Gaussian representing the Cs+-O was fixed at 3.00 A, that is, the maximum of this contribution. The other parameters were allowed to vary freely, giving a Cs+-I- distance of 3.84+/-0.05 A and coordination numbers of 7.9 and 2.7, respectively, for the Cs+-O and Cs+-I- correlations. The results on the structure of I- in the 6 molal NaI aqueous solution were also fitted to a model based on Gaussians; this gives correlations for I- -O and I- -Na+ at 3.17+/-0.06 and 3.76+/-0.06 A with respective coordination numbers of 8.8 and 1.6. The structure of I- in the 3 molal CsI solution shows overlapping contributions due to I- -H, I- -O, and I- -Cs+. The best Gaussian fit gives two peaks centered at 3.00+/-0.08 and 3.82+/-0.04 A and shows that the latter two correlations are unresolved. The hydration structures are compared with those of other alkali and halide ions. The results are also found to be in good agreement with those obtained from standard x-ray diffraction and computer simulation.     

Dehydrated and Cs+-exchanged MFI zeolites: location and population of Cs+ from in situ diffraction data as a function of temperature and degree of exchange

H-MFI type zeolitic materials of different Si/Al ratios have been completely or partially cesium-exchanged (cesium content ranging from 0.7 to 7.7 Cs/unit-cell (uc)). Examined with synchrotron X-ray powder diffractometry, an anhydrous sample with the Cs6.6H0.3Al6.9Si89.1O192 chemical composition revealed at ambient temperature the presence of five discrete Cs locations: Cs1 located in the channel intersection near a 10-ring window of the zigzag channel; Cs2 and Cs2', both located in the straight channel but 1.23 A apart; Cs3 and Cs3', both located in the zigzag channel and rather close to each other (2.51 A). The populations of the Cs species amounted to 2.61/0.81/1.85/0.86/0.47/uc for Cs1/2/2'/3/3', respectively. The continuous but multimodal nature of the C2 split site is well-described by a joint-probability density function. The 10-ring of the straight channel in the framework is highly elliptical (epsilon = 1.218). The populations for the same sites were also determined at higher temperatures: 131, 237, 344, and 450 degrees C. At 450 degrees C, Cs2' has migrated toward the center of the channel intersection, and the site separation between Cs2 and Cs2' has lengthened to 2.23 A. Using a temperature-controlled laboratory X-ray diffractometer, similar studies were carried out on partially or almost totally Cs-exchanged samples from various sources with differing Cs contents. They show that over the 0.7 to 4 Cs/uc range all the individual Cs populations vary linearly as a function of total Cs/uc present. At higher total Cs/uc content (4 to approximately 7 Cs/uc) solely Cs1 continues to do so. For Cs2+Cs2' and Cs3+Cs3', the variation is almost linear over the whole concentration range. Computer simulations using a 6-exp-1 Buckingham-type atom-atom van der Waals interaction model yield six possible Cs sites in the actual Cs6.6MFI framework structure. Four of them lie very close to those determined from difference Fourier maps using the room temperature data. A fifth one is close to the Cs2' species after thermal migration at 450 degrees C, and the sixth one is close to the center of the channel intersection. However, this latter site is observed experimentally only in the case of hydrated CsMFI phases. In the anhydrous Cs6.6MFI phase at room temperature, the shortest Cs-framework oxygen distance is Cs3'-O25 = 3.08 A, and the next shortest distances are Cs1-O26 = 3.37, Cs2-O11 = 3.34, Cs2'-O22 = 3.47, and Cs3-O20 = 3.34 A. The framework T(Si,Al) sites most involved in these contacts are the T9, T11, T12, T10, and T3 sites. This implies that these sites are prime candidates for Si/Al substitution.     

One-dimensional zigzag chains of Cs-: the structures and properties of Li+ (cryptand[2.1.1])Cs- and Cs+ (cryptand[2.2.2])Cs-

The crystal structure and properties of lithium (cryptand[2.1.1]) ceside, Li+ (C211)Cs-, are reported. Li+ (C211)Cs- is the second ceside and third alkalide with a one-dimensional (1D) zigzag chain of alkali metal anions. The distance between adjacent Cs- anions, 6 A, is shorter than the sum of the van der Waals radii, 7 A. Optical, magic angle spinning NMR, two-probe alternating and direct current conductivity, and electron paramagnetic resonance measurements reveal unique physical properties that result from the overlap of adjacent Cs- wave functions in the chain structure. The properties of cesium (cryptand[2.2.2]) ceside, Cs+ (C222)Cs-, were also studied to compare the effects of the subtle geometric changes between the two 1D zigzag chain structures. Li+ (C211)Cs- and Cs+ (C222)Cs- are both low-band-gap semiconductors with anisotropic reflectivities and large paramagnetic 133Cs NMR chemical shifts relative to Cs- (g). An electronic structure model consistent with the experimental data has sp2-hybridized Cs- within the chain and sp-hybridized chain ends. Ab initio multiconfiguration self-consistent field calculations on the ceside trimer, Cs3(3-), support this model and indicate a net bonding interaction between nearest neighbors. The buildup of electron density between adjacent Cs- anions is visualized through an electron density difference map constructed by subtracting the density of three cesium atoms from the short Cs3(3-) fragment.     

不同化学环境对Er^3＋离子的配位场能级结构的影响

首次在C3v点群对称汤中，运用双层点电荷配位场（DSCPCF）模型计算了CS3Y2I9晶体中Er^3 离子的59个配位场能级，与实验得到的能级比较，其均方根偏差为24．89cm^-1，而用点电荷配位场（PCF）模型计算的均方根偏差为29．08cm^-1，这说明双层点电荷配位场模型能更好地符合实验结果。同时，详细地分析CsLu2,Cs3Lu2Br9,Cs3Y2I9晶体中Er^3 离子能级结构的变化，由于Er^3 -X^-键共价性的增强，使Er^3 离子的能级重心发生红移，Cl→Br→I的配位场能级的分裂程序减小。     

Physicochemical characterization of the retardation of aqueous Cs+ ions by natural kaolinite and clinoptilolite minerals

The aim of this study was to carry out kinetic, thermodynamic, and surface characterization of the sorption of Cs+ ions on natural minerals of kaolinite and clinoptilolite. The results showed that sorption followed pseudo-second-order kinetics. The activation energies were 9.5 and 13.9 kJ/mol for Cs+ sorption on kaolinite and clinoptilolite, respectively. Experiments performed at four different initial concentrations of the ion revealed that the percentage sorption of Cs+ on clinoptilolite ranged from 90 to 95, compared to 28 to 40 for the kaolinite case. At the end of a 1 week period, the percentage of Cs+ desorption from clinoptilolite did not exceed 7%, while it amounted to more than 30% in kaolinite, indicating more stable fixation by clinoptilolite. The sorption data were best described using Freundlich and D-R isotherm models. Sorption showed spontaneous and exothermic behavior on both minerals, with deltaH(0) being -6.3 and -11.4 kJ/mol for Cs+ uptake by kaolinite and clinoptilolite, respectively. Expanding the kaolinite interlayer space from 0.71 to 1.12 nm using DMSO intercalation, did not yield a significant enhancement in the sorption capacity of kaolinite, indicating that the surface and edge sites of the clay are more energetically favored. EDS mapping and elemental analysis of the surface of kaolinite and clinoptilolite revealed more intense signals on the surface of the latter with an even distribution of sorbed Cs+ onto the surfaces of both minerals.     

Selective intercalation of Cs+ in the "V"-shaped cavity of a bichromophoric anion radical: Cs+ assisted pi-s-pi-delocalization of an electron

EPR studies in tetrahydrofuran, reveal that the one electron reduction of 1-(9-methyl-9H-fluoren-9-yl)-4-methylbenzene via electron transfer from cesium metal produces an anion radical that has a large affinity for the cesium cation. The affinity of this anion radical for Cs+ is so great that it will actually "suck" the Cs+ (but not Na+ or K+) right out of the grasp of 18-crown-6, leading to a cation-assisted pi-stacked complex, where the s-orbital of the metal cation is simultaneously overlapped with the pi-clouds of the phenyl and fluorenyl moieties. At ambient temperature, proton- and cesium-electron coupling constants are rapidly (on the EPR time scale) modulated as a result of the simultaneous existence of two interconverting conformers having an averaged cesium splitting (a(Cs)) of about 1.6 G. The pi-s-pi-electronic coupling can be turned on or off via the addition or removal of cesium cations. Analogous pi-s-pi-electronic coupling is observed in the 1,4-bis(9-methyl-9H-fluoren-9-yl)benzene-cesium system.     

Interaction of Cs+, Sr2+ and Gd3+ with humin

Humin is separated from a soil sample and characterized by elemental analysis, IR and potentiometric titration. These investigations indicated that humin displayed similar characteristics as humic acid. The sorption behavior of¹³⁷Cs,⁹⁰Sr and¹⁵³Gd with humin was investigated from aqueous solution. The results indicated that the sorption process follows the order: Gd³⁺≫Sr²⁺>Cs⁺. It was time dependent and increased with pH. The sorption in the presence of humic acid or EDTA showed that both form a metal-ligand complex and consequently decrease the % uptake.     

Thermodynamic study of the complexation of p-isopropylcalix[6]arene with Cs+ cation in dimethylsulfoxide-acetonitrile binary media

The complexation reactions between the macrocyclic ionophore, p-isopropylcalix[6]arene and Cs+ cation were studied in dimethylsulfoxide-acetonitrile (DMSO-AN) binary non-aqueous solvents at different temperatures using a conductometry method. The conductance data show that the stoichiometry of the (p-isopropylcalix[6]-arene·Cs)+ complex in all binary mixed solvents is 1:1. The stability of the complexes is affected by the composition of the binary solvent media and a non-linear behavior was observed for changes of log K(f) of the complex versus the composition of the binary mixed solvents. The thermodynamic parameters (DH°(c) and DS°(c)) for formation of (p-isopropyl-calix[6]arene·Cs)+ complex were obtained from temperature dependence of the stability constant and the obtained results show that the (p-isopropylcalix[6]arene·Cs)+ complex is enthalpy destabilized, but entropy stabilized, and the values of the mentioned parameters are affected strongly by the nature and composition of the binary mixed solvents.