稀土(III)-冠醚配位反应的热力学性质: II. 镧系(III)高氯酸 盐与二苯并18- 冠-6在无水乙腈中配位反应的量热滴定研究

用滴定量热计于298.15K测定了除钷、镥以外的全部十三种镧系(III)高氯酸盐与二苯并-18-冠-6在无水乙腈中的配位作用。借助计算机用自编程序算出了配位反应的生成常数和焓变,进而算出了配位反应的自由能变化和熵变化。探讨了镧系(III)阳离子对配位反应的影响。此外,还比较了几种不同冠醚与高氯酸镧在无水乙腈中配位反应的热力学性质。     

稀土(Ⅲ)-冠醚配位反应的热力学性质 Ⅱ. 镧系(Ⅲ)高氯酸盐与二苯并18-冠-6在无水乙腈中配位反应的量热滴定研究

用滴定量热计于298.15 K测定了除钷、镥以外的全部十三种镧系(Ⅲ)高氯酸盐与二苯并-18-冠-6在无水乙腈中的配位作用.借助计算机用自编程序算出了配位反应的生成常数和焓变,进而算出了配位反应的自由能变化和熵变化.探讨了镧系(Ⅲ)阳离子对配位反应的影响.此外,还比较了几种不同冠醚与高氯酸镧在无水乙腈中配位反应的热力学性质.     

稀土(III)-冠醚配位反应的热力学性质I:稀土(III)高氯酸盐与苯-15-冠-5-在乙腈溶液中配位反应的量热滴定研究

用量热滴定法于298.15K测定了除钪、钷以外的全部十五种稀土(III)高氯酸盐与苯并-15-冠-5在乙腈溶液中的配位作用。借助计算机算出了配合物的稳定常数和配位焓, 进而算出了配位自由能和配位熵。结果表明:十五种稀土(III)离子与苯并-15-冠-5都可以配位, 配位焓为正值;La^3^+配合物最稳定, Ce^3^+次之, 其余稀土(III)离子配合物稳定性变小, 但彼此差别不大, 在Tb处有突变;熵在配合物形成时起稳定化作用。     

稀土(III)-冠醚配位反应的热力学性质I:稀土(III)高氯酸盐与苯-15-冠-5-在乙腈溶液中配位反应的量热滴定研究

用量热滴定法于298.15K测定了除钪、钷以外的全部十五种稀土(III)高氯酸盐与苯并-15-冠-5在乙腈溶液中的配位作用。借助计算机算出了配合物的稳定常数和配位焓, 进而算出了配位自由能和配位熵。结果表明:十五种稀土(III)离子与苯并-15-冠-5都可以配位, 配位焓为正值;La^3^+配合物最稳定, Ce^3^+次之, 其余稀土(III)离子配合物稳定性变小, 但彼此差别不大, 在Tb处有突变;熵在配合物形成时起稳定化作用。     

高氯酸镧与18—冠—6在乙腈溶液中配位反应的量热滴定研究

用量热滴定法于298.15K测定了高氯酸镧与18—冠—6在无水乙腈溶液中的配位作用.(?)助计算机求得了配合物的稳定常数和配位焓,进而算出了配位自由能和配位熵.配位反应为放热反应.     

Fe(III)与2,3-二羟基苯磺酸钠配位反应的动力学研究

[H+]在0.01～0.70mol?L-1范围内,离子强度为1.00mol?L-1,[Fe(III)]>>[配体]、[H+]>>[配体]的条件下,研究了Fe(III)与2,3-二羟基苯磺酸钠(Tiron)的配位反应.发现当[H+]≤3.00×10-2mol?L-1时,[Fe(III)]2对反应速率有明显的贡献.求得了相关反应的动力学参数,从而揭示了FeOH2+和FeOH24+与Tiron配位的解离反应途径及FeOH32+的缔合反应机制,并提出了该配位反应的可能机理.     

稀土(Ⅲ)-冠醚配位作用的热力学性质——Ⅱ.臂式15-冠-5和臂式18-冠-6与稀土(Ⅲ)硝酸盐在无水乙腈溶液中配位反应的量热滴定

本文用量热滴定研究了N-苄基-单氮杂-15-冠-5与稀土(Ⅲ)硝酸盐(La,Ce,Pa,Nd,Sm,En,Gd,Tb,Dy,Ho,Er,Yb)和N-苄基-单氮杂-18-冠-6与稀土(Ⅲ)硝酸盐(La和Co)在无水乙腈溶液中,298.15 K时配位作用的热力学性质、化学计量法表明,所有稀土硝酸盐均与臂式冠醚形成1∶1配合物.实验中,由联接的计算机直接算出了配合物的稳定常数和配位反应的热焓,进而算出了配位自由能和配位熵.从热力学的观点,讨论了冠醚环的尺寸效应、空间构型等对配位稳定性的影响.     

稀土(Ⅲ)-冠醚配位反应的热力学性质 Ⅰ.稀土(Ⅲ)高氯酸盐与苯并-15-冠-5在乙腈溶液中配位反应的量热滴定研究

用量热滴定法于298.15K测定了除钪、钷以外的全部十五种稀土(Ⅲ)高氯酸盐与苯并-15-冠-5在乙腈溶液中的配位作用.借助计算机算出了配合物的稳定常数和配位焓,进而算出了配位自由能和配位熵.结果表明:十五种稀土(Ⅲ)离子与苯并-15-冠-5都可以配位,配位焓为正值;La~(3+)配合物最稳定,Ce~(3+)次之,其余稀土(Ⅲ)离子配合物的稳定性变小,但彼此差别不大,在Tb处有突变;熵在配合物形成时起稳定化作用.     

稀土(Ⅲ)-冠醚配位作用的热力学性质Ⅱ:臂式15-冠-5和臂式18-冠-6与稀土(Ⅲ)硝酸盐在无水乙腈溶液中配位的量热滴定

本文用量热滴定研究了N-苄基-单氮杂-15-冠-5与稀土(Ⅲ)硝酸盐(La,Ce,Pa,Nd,Sm,En,Gd,Tb,Dy,Ho,Er,Yb)和N-苄基-单氮杂-18-冠-6与稀土(Ⅲ)硝酸盐(La和Ce)在无水乙腈溶液中,298.15K时配位作用的热力学性质、化学计量法表明,所有稀土硝酸盐均与臂式冠醚形成1:1配合物.实验中,由联接的计算机直接算出了配合物 的稳定常数和配位反应的热焓,进而算出了配位自由能和配位熵.从热力学的观点,讨论了冠醚环的尺寸效应、空间构型等对配位稳定性的影响.     

稀土(Ⅲ)-冠醚配位作用的热力学性质Ⅱ:臂式15-冠-5和臂式18-冠-6与稀土(Ⅲ)硝酸盐在无水乙腈溶液中配位的量热滴定

本文用量热滴定研究了N-苄基-单氮杂-15-冠-5与稀土(Ⅲ)硝酸盐(La,Ce,Pa,Nd,Sm,En,Gd,Tb,Dy,Ho,Er,Yb)和N-苄基-单氮杂-18-冠-6与稀土(Ⅲ)硝酸盐(La和Ce)在无水乙腈溶液中,298.15K时配位作用的热力学性质、化学计量法表明,所有稀土硝酸盐均与臂式冠醚形成1:1配合物.实验中,由联接的计算机直接算出了配合物 的稳定常数和配位反应的热焓,进而算出了配位自由能和配位熵.从热力学的观点,讨论了冠醚环的尺寸效应、空间构型等对配位稳定性的影响.     

冠醚与金属离子配位作用的扩环效应

在冠醚与阳离子配位作用的热力学性质研究中，含苯并冠醚与金属离子配伍作用的能力低于母体冠醚[1]．一般认为，这是由于苯环的吸电子效应降低了邻近二个供电氧原子的电荷密度所致，而很少注意引入亚甲基降低苯环的吸电子效应对冠醚配伍作用的影响．我们近来的研究表明，在较阶队骨格冠醚分子中引入额外的亚甲基，与母体冠醚相比，对于键和钠离子具有高度的选择性．这对于设计和合成具有高选择性的功能冠醚，可作为一个较有力的。具［2-4］．为了进一步探索在给定供电氧原子的情况下，冠醚的扩环效应，我们研究了含二苯并冠醚（化合物I-m）…     

Use of factor analysis and liquid chromatography to determine the number of species in reactions of potassium ions with selected polyethers

Abstract factor analysis is used to determine the number of species in chemical systems from data obtained by high-performance liquid chromatography. Retention data for the systems involving the reaction between potassium ions and three polyethers, benzo-5-crown-5, dibenzo-18-crown-6, and dibenzo-24-crown-8, were obtained in methanol at room temperature. The experimental data were factor-analyzed in order to yield the number of species in the reacting system. In addition to the usual criteria, it is proposed that tree-dimensional graphs of calculated data be compared to three-dimensional graphs of raw data in order to evaluate the factor space. It is also suggested that the three-dimensional graphs showing the residual error matrix be examined as a tool in the evaluation of the factor space. Two species were found from the reaction between benzo-15-crown-5 and potassium, one from dibenzo-18-crown-6-, and there from dibenzo-24-crown-8 in methanol.     

New lariat ether carboxylic and hydroxamic acids: Synthesis and lanthanide ion complexation

Twenty-six new lariat ether carboxylic and hydroxamic acids based upon dibenzo-13-crown-4, dibenzo-14-crown-4, dibenzo-16-crown-5 and dibenzo-19-crown-6 ring systems are synthesized and the solid-state structure for a dibenzo-19-crown-6 lariat ether hydroxamic acid is determined. The efficiency and selectivity for lanthanide ion extraction into chloroform by these proton-ionizable lariat ethers is strongly influenced by the crown ether ring size, lipophilic group attachment site and identity of the acidic function. In general, the lariat ether hydroxamic acids were more efficient and selective lanthanide ion extractants than the corresponding lariat ether carboxylic acids. The ¹H nmr and ir binding studies indicate that both the macrocyclic polyether unit and the proton-ionizable group are involved in lanthanide ion complexation.     

稀土(Ⅲ)-冠醚配位反应的热力学性质

自1967年C.J.Pedersen首次合成冠醚并发现其配位特性以来,稀土冠醚配合物的研究工作发展迅速,特别是对固体配合物的合成及其性质的表征做了大量工作,但对其在溶液中热力学性质的研究却不多见,而且所用方法仅为电位法、NMR法、电导法等,用量热滴定法的报道很少。近来,国外已有人做了一些工作,国内也开始了这方面的研究,但研究     

Differential pulse polarographic studies of mercury complexes with some crown ethers in nonaqueous solvents

The complex formation of Hg(2+) with some macrocyclic crown ethers in nitrobenzene, acetonitrile and dimethylformamide solutions was studied by differential pulse polarography at 25 degrees C. The stoichiometry and stability of the complexes were determined by monitoring the shift in the Hg(2+) differential pulse peak potential against the ligand concentration. The stability of the resulting 1:1 complexes vary in the order dicyclohexyl-18-crown-6 > 18-crown-6 > 15-crown-5 > dibenzo-18-crown-6 > dibenzo-24-crown-8 > benzo-15-crown-5 > 12-crown-4. There is an inverse relationship between the complex stability and the Gutmann donor number of solvents.     

Acylation of Dibenzo-18-crown-6 with Alkali-metal Acetates in Polyphosphoric Acid

The acylation of dibenzo-18-crown-6 by lithium, sodium, and potassium acetates in polyphosphoric acid was studied. Complexes of dibenzo-18-crown-6 with the acetates were obtained. A new method is proposed for the production of mono- and diacetyldibenzo-18-crown-6 by the reaction of dibenzo-18-crown-6 complexes with metal acetates in polyphosphoric acid. __________ Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 8, pp. 1146–1149, August, 2005.     

Thermal decomposition of metal complexes IV. Lanthanide(III) complexes with dibenzo-18-crown-6

The solid-state thermal dissociation reactions of the complexes of all the lanthanide(III) nitrates and thiocyanates (except Pm) with the cyclic polyether dibenzo-18-crown-6 were investigated. Thermal analysis was carried out in a dynamic atmosphere of dry nitrogen and under reduced pressure (5·10^?2 mm Hg). In both the conditions examined, the two series of complexes exhibit different thermal behaviours. The values of enthalpy change and “activation energy” for the dissociation reactions of the complexes with lanthanide thiocyanates show a periodic trend along the lanthanide series.     

The influence of acetonitrile on complex formation of crown ethers containing different donor atoms

The complexation reactions of crown ethers with monovalent cations and Ba²⁺ were studied in acetonitrile solutions by means of calorimetric and potentiometric titration. The reaction enthalpies measured clearly demonstrate the influence of the interactions between 18-crown-6 and the acetonitrile solvent molecules. Changing the donor atoms or other substituents on the ligand molecule can exert a strong influence on the interactions with the solvent. Thus, all the reaction enthalpies measured for the reaction of 15-crown-5 with different cations are higher compared with 18-crown-6. On comparison with results in methanol, an approximate estimation is made of the influence of solvent molecules on the reaction enthalpies measured in acetonitrile. Due to the strong interaction between silver ion and acetonitrile, complex formation is only observed with crown ethers containing additional nitrogen or sulphur donor atoms.     

Complex Formation of Potassium Hexachloroplatinate with 18-Crown-6 and Dibenzo-18-Crown-6 in Acetonitrile

The products of the reactions between potassium hexachloroplatinate {K₂PtCl₆} and 18-crown-6 or dibenzo-18-crown-6 in acetonitrile were studied. Pure crystalline compounds [2K·2(18-crown-6)· 2CH₃CN]²⁺·[PtCl₆]^2-·2H₂O, [2K·dibenzo-18-crown-6·CH₃CN]^{2 +}·[PtCl₆]^{2 -}, and [2K·dibenzo-18-crown-6·CH₃CN]^{2 +}·[Pt₂Cl₁₀]^{2 -} were obtained. Physicochemical properties of these compounds were studied, and their near- and far-IR IR spectra and thermogravimetric curves were considered. The composition of the complexes is determined by metal:ligand molar ratio and crown ether nature. It was found that acetonitrile is coordinated via the nitrogen atom.     

Über das Fluoreszenzthermochrome Acetonitrilo-Kupferjodid mit Dibenzo-18-Krone-6

About the Fluorescence Thermochromism of Acetonitrile Copper Iodide with Dibenzo-18-Crown-6 Copper iodide reacts in actonitrile solution with dibenzo-18-crown-6 to form a compound,(CuJ)₄(CH₃CN)₄(db-18-c-6), which fluoresces yellow at 298K, but pink at 77 K. It decomposes at 55.3°C. (5 Torr) by lost of acetonitrile and a heterogeneous mixture of copper iodide and polyether results. In absence of dibenzo-18-crown-6, copper iodide forms with acetonitrile a heterogeneous mixture of copper iodide and polyether results. In absence of dibenzo-18-crown-6, copper iodide forms with acetonitrile a solvate CuJ. CH₃CN. It also shows fluorescence thermochromism (yellow at 298 K, but green at 77 k) but decomposes at 0°C and 760 Torr. The luminescences pectra of the macrocyclic polyether complex at 298 K is redshifted. This probably results from intersection between the crown and the acetonitrile copper iodide.