多足配体稀土超分子配合物及其蒙脱土复合发光材料的研究
摘要
多足配体与金属离子配位时,能够表现出特有的选择性配位能力、类球形配位空穴和新颖的配位结构,从而成为近年来配位化学的研究热点。稀土离子具有独特的电子结构和成键特征,配位数高且多变,使得具有光、电、磁功能的稀土超分子配合物的组装成为一个具有挑战性的课题。众多已在功能超分子化学中表现出潜在应用前景的多足配体中,酰胺型多足配体在制备具有强荧光性质的稀土配合物中表现得尤其引人注目。此类多足配体具有合成简单、结构可调和共轭敏化基团可换等优点。通过调整配体的功能基团可以实现配合物优良的荧光性质。为了进一步研究和探讨酰胺型多足配体对稀土离子的配位选择性以及配体骨架结构、功能末端基和抗衡阴离子对配合物荧光性质的影响,本论文报道了酰胺型多足配体L~Ⅰ~L~Ⅸ及其稀土超分子配合物的合成与表征,并对配合物的荧光性质进行了比较系统的研究。稀土配合物的光、热和化学稳定性较差,限制了其在很多领域的实际应用,而无机基质材料大多具有良好的光、热和化学稳定性。因此,将二者复合,是改善稀土配合物的发光性能和光、热和化学稳定性、开发新型稀土发光材料、拓宽稀土发光配合物应用领域的新途径。本论文将酰胺型多足配体稀土配合物插层组装到蒙脱土的层板间,制备出具有层柱状结构的稀土配合物-蒙脱土超分子复合发光材料,复合材料的发光性能和光、化学稳定性较相应纯稀土配合物有显著改善。
本论文共分六章:
第一章:简要综述了近年来多足配体超分子配合物、稀土发光配合物和蒙脱土复合材料的研究进展。
第二章:以乙酰苄胺和乙酰苯胺为功能末端基合成出两个具有相同柔性骨架的三足配体L~Ⅰ和L~Ⅱ,并合成了五种阴离子稀土盐的10个系列共65个稀土配合物。研究结果表明配合物均为双帽型稀土有机配阳离子结构。对配合物的超分子结构进行了深入研究,探讨了不同阴离子对配合物结构的影响以及分子间氢键、π-π堆积在构筑新颖超分子结构中的作用。
第三章:以乙酰苄胺为功能末端基合成出四个具有不同刚性骨架的多足配体L~Ⅲ~L~Ⅵ,并合成了4个系列共28个稀土苦味酸盐配合物。配合物的晶体结构研究表明,配体L~Ⅲ、L~Ⅳ均能与稀土苦味酸盐形成1:1(M:L)型配合物,三个苦味酸根离子均参与配位,有效地保护了中心稀土离子,使其免受环境影响,有望获得发光性能优良的稀土功能配合物。
第四章:以水杨酰苄胺和(间)水杨酰胺甲基吡啶为功能末端基合成出三个刚性骨架的多足桥联配体L~Ⅶ~L~Ⅸ,并合成出配体与稀土硝酸盐、稀土高氯酸盐的6个系列共31个配合物。晶体结构研究表明,配体L~Ⅶ、L~Ⅷ稀土硝酸盐配合物分别为多足配体稀土配合物中非常少见的(6,3)蜂巢状和(10,3)-a型配位聚合结构。
第五章:对铕、铽配合物进行了荧光性质研究。结果表明,所有末端基对稀土离子均具有良好的敏化作用。配体的骨架结构、侧链数目和功能末端基以及抗衡阴离子对稀土配合物的荧光强度均产生一定影响。
第六章:以第二章合成出的配体L~Ⅰ、L~Ⅱ的铕/铽配合物为原料制备出蒙脱土复合发光材料,用元素分析、XRD和IR对其进行了表征,并对复合材料的荧光性质进行了初步研究。结果表明,三足配体稀土有机配阳离子可通过室温溶液离子交换反应插层组装到蒙脱土的层板间,主-客体间以超分子作用力(此处主要是静电作用)结合成具有规整层柱结构的复合材料。复合材料较纯化合物有着更好的光、化学稳定性。
本论文涉及到的配体:
L~Ⅰ:2,2',2”-胺三乙酰苄胺
L~Ⅱ:2,2',2”-胺三乙酰苯胺
L~Ⅲ:三甘酰双苄胺
L~Ⅳ:2,2'-(1,2-苯双氧代)双乙酰苄胺
L~Ⅴ:2,2'-(1,2-萘双氧代)双乙酰苄胺
L~Ⅵ:2,2',2”-(1,2,3-苯三氧代)双乙酰苄胺
L~Ⅶ:1,4-二[(2'-苄胺甲酰基苯氧基)-甲基]-2,5-二甲苯
L~Ⅷ:1,3,5-三[(2'-苄胺甲酰基苯氧基)-甲基]苯
L~Ⅸ:1,4-二{[2'-(3-吡啶甲胺甲酰基苯氧基)]-甲基}-2,5-二甲苯
Podand-type ligands have drawn much attention in recent years,mainly due to their particular selective coordinating capacity,spheroidal cavities,and novel coordinational structure when they coordinate with metal ions.Rare earth elements are a group of special inorganic ions with good luminescent,electronic and magnetic properties.Among these podands having potential applications in functional supramolecular chemistry,amide-type podands have drawn much attention in preparing rare earth complexes with strongly luminescent properties. Amide-type podand ligands have the advantages in simple synthesis,adjustable structure and changeable sensitive conjugate groups,which make their complexes indicating good luminescent properties.In order to investigate the coordination properties of the amide-type podand ligands with rare earth ions,and the influence of different skeleton and the functional terminal groups of the ligands and different anions to luminescent properties of the rare earth complexes,this dissertation reported the synthesis and characterization of amide-type podand ligands L~Ⅰ~L~Ⅸ. The luminescent properties of the complexes have also been comprehensively investigated.The application of the rare earth complexes are limited by the poor optical,thermal and chemical stabilities.Stable inorganic solid matrices which can change the structure and chemical microenvironment of guest molecules or ions, could affect the luminescent properties of guest molecules or ions distinctly.So the hybrid of the rare earth organic complexes with suitable inorganic solid matrices is a desirable way to improve the luminescent properties and the stabilities of the complexes,develop novel rare earth luminescent materials and widen their application field.We intercalate rare earth luminescent complexes with amide-type podands into the interlayer space of montmorillonite(MT)and obtain novel rare earth complex-MT supramolecular composite luminescent materials which have better luminescence properties,better chemical and optical stabilities compared with their pure complexes.
The dissertation includes following six chapters:
1.A brief review of investigation progress of podand ligands supramolecular complexes,rare earth luminescent complexes and composite montmorillonite materials were summarized.
2.Two same flexible framework of tripodal ligands L~Ⅰand L~Ⅱusing [N-(phenylmethyl)]acetamide and(N-phenyl)acetamide as terminal groups and 65 rare earth complexes include rare earth salts of five different anions have been synthesized and characterized.The research results show that all the complexes have bicapped structures of lanthanide-organic coordination cations.The structures of complexes can be affected remarkably by the counter anions.Based on crystal diffraction analysis,the influence of the counter anions to the complex structures, hydrogen bonds andπ-πstacking interactions in building novel supramolecular, and space topological structures in supermolecules have been studied.
3.Four podand ligands L~Ⅲ-L~Ⅵcontaining different rigid framework and using [N-(phenylmethyl)]aeetamide as terminal groups and their 28 rare earth picrate complexes have been synthesized and characterized.The single-crystal X-ray analysis of the picrates complexes of L~Ⅲand L~Ⅳreveals that there are 1:1(M:L) type complexes with the rare earth ions coordinated with three bidentate picrate groups and four oxygen donor atoms from the tetradentate ligand.Based on crystal diffraction analysis,hydrogen bonds andπ-πstacking interactions in building novel supramolecular,and space topological structures in supermolecules have been studied.
4.Three different podand ligands L~Ⅲ-L~Ⅵwith rigid framework using N-benzylsalicylamide and N-(3-pyridylmethyl)salicylamide as terminal groups and 31 rare earth nitrate and perchlorate complexes have been synthesized and characterized.The crystal structures of the complexes show that all the rare earth nitrate complexes of L~Ⅶand L~Ⅷare(6,3)honeycomb and(10,3)-a type coordination polymers,which are very uncommon in the rare earth complexes with podand ligands.
5.Photoluminescence studies of europium and terbium complexes show that all the terminal groups have good sensitive function to europium and terbium ions. The framework and terminal groups of ligands,the counter anions have effects on the luminescent properties of rare earth complexes.
6.The Eu/Tb complexes prepared in chapter two were intercalated into the interlayer space of MT by solid-liquid ion exchanging,and formed Eu/Tb-organic montmorillonite composite luminescent materials.The results of characterization show that the guest complex ions arranged in the interlayer space of MT in the formation of a monolayer and the composite materials formed through the supramolecular interactions between the host layers and the guest complex ions had regular layered structure.The luminescent properties of the composite materials were preliminarily studied.The result shows that the composite materials have better chemical and optical stabilities compared with their pure complexes.
The ligands involved in the dissertation are listed as follows:
L~Ⅰ:2,2',2"-nitrilotris-(N-phenylmethyl)acetamide
L~Ⅱ:2,2',2"-nitrilotris-(N-phenyl)acetamide
L~Ⅲ:2,2'-[(1,2-ethanediyl)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅳ:2,2'-[(1,2-phenylene)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅴ:2,2'-[(1,2-naphthalene)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅵ:2,2',2"-[(1,2,3-phenylene)tri(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅶ:2,5-bimethyl-1,4-bis {[(2'-benzylaminoformyl)phenoxyl]methyl} benzene
L~Ⅷ:1,3,5-tris{[(2'-benzylaminoformyl)phenoxyl]methyl} benzene
L~Ⅸ: 2,5-dimethyl-1,4-di{[2'-(3-pyridylmethylaminoformyl)phenoxyl]methyl}benzene
本论文共分六章:
第一章:简要综述了近年来多足配体超分子配合物、稀土发光配合物和蒙脱土复合材料的研究进展。
第二章:以乙酰苄胺和乙酰苯胺为功能末端基合成出两个具有相同柔性骨架的三足配体L~Ⅰ和L~Ⅱ,并合成了五种阴离子稀土盐的10个系列共65个稀土配合物。研究结果表明配合物均为双帽型稀土有机配阳离子结构。对配合物的超分子结构进行了深入研究,探讨了不同阴离子对配合物结构的影响以及分子间氢键、π-π堆积在构筑新颖超分子结构中的作用。
第三章:以乙酰苄胺为功能末端基合成出四个具有不同刚性骨架的多足配体L~Ⅲ~L~Ⅵ,并合成了4个系列共28个稀土苦味酸盐配合物。配合物的晶体结构研究表明,配体L~Ⅲ、L~Ⅳ均能与稀土苦味酸盐形成1:1(M:L)型配合物,三个苦味酸根离子均参与配位,有效地保护了中心稀土离子,使其免受环境影响,有望获得发光性能优良的稀土功能配合物。
第四章:以水杨酰苄胺和(间)水杨酰胺甲基吡啶为功能末端基合成出三个刚性骨架的多足桥联配体L~Ⅶ~L~Ⅸ,并合成出配体与稀土硝酸盐、稀土高氯酸盐的6个系列共31个配合物。晶体结构研究表明,配体L~Ⅶ、L~Ⅷ稀土硝酸盐配合物分别为多足配体稀土配合物中非常少见的(6,3)蜂巢状和(10,3)-a型配位聚合结构。
第五章:对铕、铽配合物进行了荧光性质研究。结果表明,所有末端基对稀土离子均具有良好的敏化作用。配体的骨架结构、侧链数目和功能末端基以及抗衡阴离子对稀土配合物的荧光强度均产生一定影响。
第六章:以第二章合成出的配体L~Ⅰ、L~Ⅱ的铕/铽配合物为原料制备出蒙脱土复合发光材料,用元素分析、XRD和IR对其进行了表征,并对复合材料的荧光性质进行了初步研究。结果表明,三足配体稀土有机配阳离子可通过室温溶液离子交换反应插层组装到蒙脱土的层板间,主-客体间以超分子作用力(此处主要是静电作用)结合成具有规整层柱结构的复合材料。复合材料较纯化合物有着更好的光、化学稳定性。
本论文涉及到的配体:
L~Ⅰ:2,2',2”-胺三乙酰苄胺
L~Ⅱ:2,2',2”-胺三乙酰苯胺
L~Ⅲ:三甘酰双苄胺
L~Ⅳ:2,2'-(1,2-苯双氧代)双乙酰苄胺
L~Ⅴ:2,2'-(1,2-萘双氧代)双乙酰苄胺
L~Ⅵ:2,2',2”-(1,2,3-苯三氧代)双乙酰苄胺
L~Ⅶ:1,4-二[(2'-苄胺甲酰基苯氧基)-甲基]-2,5-二甲苯
L~Ⅷ:1,3,5-三[(2'-苄胺甲酰基苯氧基)-甲基]苯
L~Ⅸ:1,4-二{[2'-(3-吡啶甲胺甲酰基苯氧基)]-甲基}-2,5-二甲苯
Podand-type ligands have drawn much attention in recent years,mainly due to their particular selective coordinating capacity,spheroidal cavities,and novel coordinational structure when they coordinate with metal ions.Rare earth elements are a group of special inorganic ions with good luminescent,electronic and magnetic properties.Among these podands having potential applications in functional supramolecular chemistry,amide-type podands have drawn much attention in preparing rare earth complexes with strongly luminescent properties. Amide-type podand ligands have the advantages in simple synthesis,adjustable structure and changeable sensitive conjugate groups,which make their complexes indicating good luminescent properties.In order to investigate the coordination properties of the amide-type podand ligands with rare earth ions,and the influence of different skeleton and the functional terminal groups of the ligands and different anions to luminescent properties of the rare earth complexes,this dissertation reported the synthesis and characterization of amide-type podand ligands L~Ⅰ~L~Ⅸ. The luminescent properties of the complexes have also been comprehensively investigated.The application of the rare earth complexes are limited by the poor optical,thermal and chemical stabilities.Stable inorganic solid matrices which can change the structure and chemical microenvironment of guest molecules or ions, could affect the luminescent properties of guest molecules or ions distinctly.So the hybrid of the rare earth organic complexes with suitable inorganic solid matrices is a desirable way to improve the luminescent properties and the stabilities of the complexes,develop novel rare earth luminescent materials and widen their application field.We intercalate rare earth luminescent complexes with amide-type podands into the interlayer space of montmorillonite(MT)and obtain novel rare earth complex-MT supramolecular composite luminescent materials which have better luminescence properties,better chemical and optical stabilities compared with their pure complexes.
The dissertation includes following six chapters:
1.A brief review of investigation progress of podand ligands supramolecular complexes,rare earth luminescent complexes and composite montmorillonite materials were summarized.
2.Two same flexible framework of tripodal ligands L~Ⅰand L~Ⅱusing [N-(phenylmethyl)]acetamide and(N-phenyl)acetamide as terminal groups and 65 rare earth complexes include rare earth salts of five different anions have been synthesized and characterized.The research results show that all the complexes have bicapped structures of lanthanide-organic coordination cations.The structures of complexes can be affected remarkably by the counter anions.Based on crystal diffraction analysis,the influence of the counter anions to the complex structures, hydrogen bonds andπ-πstacking interactions in building novel supramolecular, and space topological structures in supermolecules have been studied.
3.Four podand ligands L~Ⅲ-L~Ⅵcontaining different rigid framework and using [N-(phenylmethyl)]aeetamide as terminal groups and their 28 rare earth picrate complexes have been synthesized and characterized.The single-crystal X-ray analysis of the picrates complexes of L~Ⅲand L~Ⅳreveals that there are 1:1(M:L) type complexes with the rare earth ions coordinated with three bidentate picrate groups and four oxygen donor atoms from the tetradentate ligand.Based on crystal diffraction analysis,hydrogen bonds andπ-πstacking interactions in building novel supramolecular,and space topological structures in supermolecules have been studied.
4.Three different podand ligands L~Ⅲ-L~Ⅵwith rigid framework using N-benzylsalicylamide and N-(3-pyridylmethyl)salicylamide as terminal groups and 31 rare earth nitrate and perchlorate complexes have been synthesized and characterized.The crystal structures of the complexes show that all the rare earth nitrate complexes of L~Ⅶand L~Ⅷare(6,3)honeycomb and(10,3)-a type coordination polymers,which are very uncommon in the rare earth complexes with podand ligands.
5.Photoluminescence studies of europium and terbium complexes show that all the terminal groups have good sensitive function to europium and terbium ions. The framework and terminal groups of ligands,the counter anions have effects on the luminescent properties of rare earth complexes.
6.The Eu/Tb complexes prepared in chapter two were intercalated into the interlayer space of MT by solid-liquid ion exchanging,and formed Eu/Tb-organic montmorillonite composite luminescent materials.The results of characterization show that the guest complex ions arranged in the interlayer space of MT in the formation of a monolayer and the composite materials formed through the supramolecular interactions between the host layers and the guest complex ions had regular layered structure.The luminescent properties of the composite materials were preliminarily studied.The result shows that the composite materials have better chemical and optical stabilities compared with their pure complexes.
The ligands involved in the dissertation are listed as follows:
L~Ⅰ:2,2',2"-nitrilotris-(N-phenylmethyl)acetamide
L~Ⅱ:2,2',2"-nitrilotris-(N-phenyl)acetamide
L~Ⅲ:2,2'-[(1,2-ethanediyl)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅳ:2,2'-[(1,2-phenylene)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅴ:2,2'-[(1,2-naphthalene)bis(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅵ:2,2',2"-[(1,2,3-phenylene)tri(oxy)]bis[N-(phenylmethyl)]acetamide
L~Ⅶ:2,5-bimethyl-1,4-bis {[(2'-benzylaminoformyl)phenoxyl]methyl} benzene
L~Ⅷ:1,3,5-tris{[(2'-benzylaminoformyl)phenoxyl]methyl} benzene
L~Ⅸ: 2,5-dimethyl-1,4-di{[2'-(3-pyridylmethylaminoformyl)phenoxyl]methyl}benzene
引文
1.Pederson C.J.,Host-Guest Chemistry:Complexes between organic compounds simulate the substrate selectivity of enzymes.,J.Am.Chem.Soc.,1967,89,2495-2496
2.Pederson C.J.,Cyclic polyethers and their complexes with metal salts.,J.Am.Chem.Soc.1967,89,7017-7036
3.Cram D.J.,Cram J.M.,Host-Guest Chemistry:Complexes between organic compounds simulate the substrate selectivity of enzymes.,Science,1974,183,803-809
4.Lehn J.M.,Supramolecular Chemistry- Scope and perspectives molecules,Supermolecules,and molecular devices(Nobel Lecture).,Angew.Chem.Int.Ed.,1988,27,89-112
5.Kumara Swamy K.C.,Kumaraswamy S.,Kommana P.,Very Strong C-H…O,N-H…O,and O-H…O Hydrogen Bonds Involving a Cyclic Phosphate.,J.Am.Chem.Soc.,2001,123(50),12642-12649
6.Demeshko S.,Dechert S.,Meyer F.,Anion-π Interactions in a Carousel Copper(Ⅱ)-Triazine Complex.,J.Am.Chem.Soc.,2004,126(14),4508-4509
7.Vilar R.,Anion-templated synthesis.,Angew.Chem.Int.Ed.,2003,42(13),1460-1477
8.Structural determinants of water permeation through aquaporin-1.,Murata K.,Mitsuoka K.,Hirai T.,Walz T.,Agrek P.,Heymann J.B.,Engel A.,Fujiyoshi Y.,Nature,2000,407,599-605
9.Gao T.,Yan P.-F.,Li G.-M.,Hou G.-F.,Gao J.-S.,N,N'-Ethylene-bis(3-methoxysalicylideneimine)mononuclear(4f)and heterodinuclear (3d-4f)metal complexes:Synthesis,crystal structure and luminescent properties.,Inorg.Chim.Acta,2008,361(7),2051-2058
10.Tamboura F.B.,Haba P.M.,Gaye M.,Sall,A.S.Barry A.H.,Jouini T.,Structural studies of bis-(2,6-diacetylpyridine-bis-(phenylhydrazone))and X-ray structure of its Y(Ⅲ),Pr(Ⅲ),Sm(Ⅲ)and Er(Ⅲ)complex.,Polyhedron,2004,23(7),1191-1197
11.Wang F.-Q.,Zheng X.-J.,Wan Y.-H.,Wang K.-Z.,Jin L.-P.,Architecture of zero-,one-,two- and three-dimensional structures based on metal ions and pyrazine-2,6-dicarboxylic acid.,Polyhedron,2008,27(2),717-726
12.Dalgarno S.J.,Hardie M.J.,Atwood J.L.,Warrenc J.E.,Raston C.L.,A complex 3D 'wavy brick wall' coordination polymer based on p-sulfonatocalix arene.,New J.Chem.,2005(29),649-652
13.Dong Y.-B.,Xu H.-X.,Ma J.-P.,Huang R.-Q.,Silver(Ⅰ)Coordination Polymers Based on A Nano-Sized Bent Bis(3-acetylenylpbenyl-(4-cyanophenyl))oxadiazole Ligand:The Role of Ligand Isomerism and the Templating Effect of Polyatomic Anions and Solvent Intermediates.,Inorg.Chem.2006,45(8),3325-3343
14.Shavaleev N.M.,Bell Z.R.,Accorsi G.,Ward M.D.,Syntheses and structures of mononuclear {Re(CO)_3Cl(NN)} 'complex ligands' with a pendant imino-pyridine binding site,and preparation of some heterodinuclear Re(Ⅰ)-lanthanide(Ⅲ)complexes Inorg.Chim.Acta,2003,351,159-166
15.Caravan P.,Hedlund T.,Liu S.,Sjoeberg S.,Orvig C.,Potentiometric,Calorimetric,and Solution NMR Studies of a Tridentate Ligand Which has a Marked Preference for Formation of Bis(ligand)versus Mono(ligand)Lanthanide Complexes and Which Exhibits High Selectivity for Heavier Lanthanides.,J.Am.Chem.Soc.,1995,117(45),11230-11238
16.Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays:Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.,2000,39(3),496-507
17.Yang X.-P.,Kang B.-S.,Wong W.-K.,Su C.-Y.,Liu H.-Q.,Syntheses,Crystal Structures,and Luminescent Properties of Lanthanide Complexes with Tripodal Ligands Bearing Benzimidazole and Pyridine Groups.,Inorg.Chem.,2003,42(1),169-179
18.Wada A.,Honda Y.,Yarnaguchi S.,Nagatomo S.,Kitagawa T.,Jitsukawa K.,Masuda H.,Steric and Hydrogen-Bonding Effects on the Stability of Copper Complexes with Small Molecules.,Inorg.Chem.,2004,43(18),5725-5735
19.Mandon D.,Nopper A.,Litrol T.,Goetz S.,Tridentate Coordination of Monosubstituted Derivatives of the Tris(2-pyridylmethyl)amine Ligand to FeCl_3:Structures and Spectroscopic Properties of((2-Bromopyridyl)methyl)bis-(2-pyridylmethyl)amine Fe~ⅢCl_3and(((2-p- Methoxyphenyl)pyridyl)methyl)Bis(2-pyridyl-methyl)]amine Fe~ⅢCl_3 and Comparison with the Bis(2-pyridylmethyl)]amine Fe~ⅢCl_3 Complex.,Inorg.Chem.,2001,40(18),4803-4806
20.Velusamy M.,Mayilmurugan R.,Palaniandavar M.,Iron(Ⅲ)Complexes of Sterically Hindered Tetradentate Monophenolate Ligands as Functional Models for Catechol 1,2-Dioxygenases:The Role of Ligand Stereoelectronic Properties.,Inorg.Chem.,2004,43(20),6284-6293
21.Paul S.,Batik A.K.,Pang S.M.,Kar S.K.,Novel Copper(Ⅱ)Induced Formation of a Porphyrinogen Derivative:X-ray Structural,Spectroscopic,and Electrochemical Studies of Porphyrinogen Complexes of Cu(Ⅱ)and Co(Ⅲ)Complex of a Trispyrazolyl Tripodal Ligand.,Inorg.Chem.,2002,41(22),5803-5809
22.Hammes B.S.,Kieber-Emmons M.T.,Sommer R.,Rheingold A.L.,Modulating the Reduction Potential of Mononuclear Cobalt(Ⅱ)Complexes via Selective Deprotonation of Tris[(2-benzimidazolyl)methyl]amine.,Inorg.Chem.,2002,41(6),1351-1353
23.Mizuno M.,Hayashi H.,Fujinami S.,Furutachi H.,Nagatomo S.,Otake S.,Uozumi K.,Suzuki M.,Kitagawa T.,Ligand Effect on Reversible Conversion between Copper(Ⅰ)and Bis(μ-oxo)dicopper(Ⅲ)Complex with a Sterically Hindered Tetradentate Tripodal Ligand and Monooxygenase Activity of Bis(μ-oxo)dicopper(Ⅲ)Complex.,Inorg.Chem.,2003,42(25),8534-8544
24.Sunatsuki Y.,Ohta H.,Kojima M.,Ikuta Y.,Goto Y.,Matsumoto N.,Iijima S.,Akashi H., Kalzaki S.,Dahan F.,Tuchagues J.-P.,Supramolecular Spin-Crossover Iron Complexes Based on Imidazole-Imidazolate Hydrogen Bonds.,Inorg.Chem.,2004,43(14),4154-4171
25.Tor Y.,Libman J.,Shanzer.A.,Biomimetic ferric ion carders.Chiral ferdchrome analogs.,J.Am.Chem.Soc.,1987,109(21),6518-6519
26.Dayan I.,Libman J.,Shanzer A.,Felder C.E.,Lifson.S.,Regulation of molecular conformation of chiral tripodal structures by calcium-cation binding.,J.Am.Chem.Soc.,1991,113(9),3431-3439
27.Dayan I.,Libman J.,Agi Y.,Shanzer.A.,Chiral siderophore analogs:ferrichrome.,Inorg.Chem.,1993,32(8),1467-1475
28.卢会杰,尹明彩,樊耀亭,侯红卫,吴养洁.三脚架结构化合物及其配合物研究进展,无机化学学报,200l,17(4),478-488
29.Mealli C.,Ghilardi C.A.,Orlandini A.,Structural flexibility and bonding capabilities of the ligand np_3 toward the transition metals.,Coord.Chem.Rev.,1992,120,361-387
30.Clark K.A.,George T.A.,Trigonal-Bipyrarnidal Tin(Ⅳ)Complexes Containing Tetradentate Tripodal Tristhiolatophosphine Ligands:Synthesis,Characterization,Crystal Structure,and Transmetalation Reactions.,Inorg.Chem.,2005,44(2),416-422
31.Block E.,Ofori-Okai G.,Zubieta J.,2-Phosphino- and 2-phosphinylbenzenethiols:new ligand types.,J.Am.Chem.Soc.,1989,111(6),2327-2329
32.Vries N.D.,Cook J.,Jones A.G.,Davison A.,Technetium(Ⅲ)complexes with the tetradentate "umbrella" ligand tris(o-mereaptophenyl)phosphinate:x-ray structural characterization of Te(P(o-C6H4S)3)(CNC3H7)and Te(P(o-C6H4S)3)(CNC3H7)2.,Inorg.Chem.,1991,30(12),2662-2665
33.Xu Z.,Read P.W.,Hibbs D.E.,Hursthouse M.B.,Abdul Malik K.M.,Patrick B.O.,Rettig S.J.,Seid M.,Summers D.A.,Pink M.,Thompson R.C.,Orvig C.,Coaggregation of Paramagnetie d- and f-Block Metal Ions with a Podand-Framework Amine Phenol Ligand.,Inorg.Chem.,2000,39(3),508-516
34.Caravan P.,Orvig C.,Tripodal Aminophenolate Ligand Complexes of Aluminum(Ⅲ),Gallium(Ⅲ),and Indium(Ⅲ)in Water.,Inorg.Chem.,1997,36(2),236-248
35.Lowe M.P.,Caravan P.,Rettig S.J.,Orvig C.,Tightening the Hydrophobic Belt:Effects of Backbone and Donor Group Variation on Podand Ligand Complexes of the Lanthanides.,Inorg.Chem.,1998,37(7),1637-1647
36.Liu S.,Wong E.,Karunaratne V.,Rettig S.J.,Orvig C.,Highly flexible chelating ligands for Group 13 metals:design and synthesis of hexadentate(N3O3)tripodal amine phenol ligand complexes of aluminum,gallium,and indium.,Inorg.Chem.,1993,32(9),1756-1765
37.Liu S.,Wong E.,Rettig S.J.,Orvig C.,Hexadentate N3O3 amine phenol ligands for Group 13 metal ions:evidence for intrastrand and interstrand hydrogen-bonds in polydentate tripodal amine phenols.,Inorg.Chem.,1993,32(20),4268-4276
38.Armaroli N.,Accorsi G.,Barigelletti F.,Couchman S.M.,Fleming,J.S.,Harden N.C.,Jeffery J.C.,Mann K.L.V.,McCleverty J.A.,Rees L.H.,Starling S.R.,Ward M.D.,Structural and Photophysical Properties of Mononuclear and Dinuclear Lanthanide(Ⅲ)Complexes of Multidentate Podand Ligands Based on Poly(pyrazolyl)borates.,Inorg.Chem.,1999,38(25),5769-5776
39.Reeves Z.R.,Mann K.L.V.,JeVery J.C.,McCleverty J.A.,Ward M.D.,Barigelletti F.,Armaroli N.Lanthanide complexes of a new sterically hindered potentially hexadentate podand ligand based on a tris(pyrazolyl)borate core;crystal structures,solution structures and luminescence properties.,J.Chem.Soc.,Dalton Trans.,1999,349-355
40.Davies G.M.,Aarons R.J.,Motson G.R.,Jeffery J.C.,Adams H.,Faulkner S.,Ward M.D.,Structural and near-IR photophysical studies on ternary lanthanide complexes containing poly(pyrazolyl)borate and 1,3-diketonate ligands.,DaltonTrans.,2004,1136-1144
41.Careri M.,Elviri L.,Lanfranchi M.,Marchio L.,Mora C.,Pellinghelli M.A.,Versatile Ligand Behavior of Hydrotris(4-ethyl-3-methyl-5-thioxo-1,2,4-triazolyl)borate.Syntheses and Crystal Structures of Cu(Ⅰ)and Bi(Ⅲ)Complexes.,Inorg.Chem.,2003,42(6),2109-2114
42.Dodds C.A.,Lehmann M.-A.,Ojo J.F.,Reglinski J.,Spicer M.D.,Cobalt Half-Sandwich,Sandwich,and Mixed Sandwich Complexes with Soft Tripodal Ligands.,Inorg.Chem.,2004,43(16),4927-4934
43.Gorden A.E.V.,Xu J.,Raymond K.N.,Durbin P.,Rational Design of Sequestering Agents for Plutonium and Other Actinides.,Chem.Rev.,2003,103(11),4207-4282
44.Schumann H.,Meese-Marktscheffel J.A.,Esser L.,Synthesis,Structure,and Reactivity of Organometallic.pi.-Complexes of the Rare Earths in the Oxidation State Ln~(3+)with Aromatic Ligands.,Chem.Rev.,1995,95(4),865-986
45.Armaroli N.,Acoorsi G.,Barigelletti F.,Couchman S.M.,Fleming J.S.,Harden N.C.,Jeffery J.C.,Mann K.L.V.,McCleverty J.A.,Rees L.H.,Starling S.R.,Ward M.D.,Structural and Photophysical Properties of Mononuclear and Dinuclear Lanthanide(Ⅲ)Complexes of Multidentate Podand Ligands Based on Poly(pyrazolyl)borates.,Inorg.Chem.,1999,38(25),5769-5776
46.Yang X.-P.,Kang B.-S.,Wong W.-K.,Su C.-Y.,Liu H.-Q.,Syntheses,Crystal Structures,and Luminescent Properties of Lanthanide Complexes with Tripodal Ligands Bearing Benzimidazole and Pyridine Groups.,Inorg.Chem.,2003,42(1),169-179
47.Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays:Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.,2000,39(3),496-507
48.Reeves Z.R.,Mann K.L.V.,JeVery J.C.,McCleverty J.A.,Ward M.D.,Barigelletti F., Armaroli N., Lanthanide complexes of a new sterically hindered potentially hexadentate podand ligand based on a tris(pyrazolyl)borate core; crystal structures, solution structures and luminescence properties., J. Chem. Soc., Dalton Trans., 1999,349-355
49. Davies G. M., Aarons R. J., Motson G. R., Jeffery J. C., Adams, H. Faulkner S., Ward M. D., Structural and near-IR photophysical studies on ternary lanthanide complexes containing poly(pyrazolyl)borate and 1,3-diketonate ligands., Dalton Trans., 2004, 1136-1144
50. Kanesato M., Mizukami S., Houjou H., Tokuhisa H., Koyama E., Nagawa Y., Comparison of the bond lengths for the lanthanide complexes of tripodal heptadentate ligands., J. Alloy. Compd., 2004,374(1-2), 307-310
51. Heck R., Marsura A., A new symmetrically modified a-cyclodextrin tripode: selective metal complexation and fluorescence properties., Tetrahedron Letter, 2004, 45(2), 281-284
52. Horike S., Matsuda R., Tanaka D., Mizuno M., Endo K., Kitagawa S., Immobilization of Sodium Ions on the Pore Surface of a Porous Coordination Polymer., J. Am. Chem. Soc., 2006,128(13), 4222-4223
53. Su C.-Y., Cai Y.-P., Chen C.-L., Smith M. D., Kaim W., Zur Loye H.-C., Ligand-Directed Molecular Architectures: Self-Assembly of Two-Dimensional Rectangular Metallacycles and Three-Dimensional Trigonal or Tetragonal Prisms., J. Am. Chem. Soc., 2003,125(28),8595-8613
54. Wang S., Xing H., Li Y., Bai J., Pan Y., Scheer M., You X., 2D and 3D Cadmium(II) Coordination Polymers from a Flexible Tripodal Ligand of 1,3,5-Tris(carboxymethoxy)benzene and Bidentate Pyridyl-Containing Ligands with Three-, Eight- and Ten-Connected Topologies., Eur. J. Inorg. Chem., 2006, 2006(15), 3041-3053
55. Rosa D. T., Krause Bauer J. A., Baldwin M. J., Structural and Spectroscopic Studies of the Versatile Coordination Chemistry of the Chiral Ligand N,N-Bis(1-propan-2-onyl oxime)-L-methionine N'-Methylamide with Ni~(II) and Zn~(II)., lnorg. Chem., 2001, 40(7), 1606-1613
56. Reger D. L., Semeniuc R. F., Smith M. D., Synthesis of Open and Closed Metallacages Using Novel Tripodal Ligands: Unusually Stable Silver(I) Inclusion Compound., Inorg. Chem., 2003,42(25), 8137-8139
57. Yam V. W. W., Lo K. K. W., Recent advances in utilization of transition metal complexes and lanthanides as diagnostic tools., Coord. Chem. Rev., 1999,184(1), 157-240
58. Lauffer R. B., Paramagnetic metal complexes as water proton relaxation agents for NMR imaging: theory and design., Chem. Rev., 1987,87(5), 901-927
59. Vigato P. A., Tamburini S., Bertolo L., The development of compartmental macrocyclic Schiff bases and related polyamine derivatives., Coord. Chem. Rev., 2007, 251(11-12), 1311-1492
60.Shibasaki M.,Sasai H.,Arai T.,Asymmetric Catalysis with Heterobimetallic Compounds.,Angew.Chem.Int.Ed.Engl.,1997,36(12),1236-1256
61.Sabbatini N.,Guardigli M.,Lehn J.M.,Luminescent lanthanide complexes as photochemical supramolecular devices.,Coord.Chem.Rev.,1993,123(1-2),201-228
62.Suarez S.,Imbert D.,Gumy F.,Piguet C.,Bunzli J.-C.G.,Metal-Centered Photoluminescence as a Tool for Detecting Phase Transitions in Eu~Ⅲ- and Tb~Ⅲ-Containing Metallomesogens.,Chem.Mater.,2004;16(17),3257-3266
63.Tobita S.j.,Arakawa M.,Tanaka.I.,The paramagnetic metal effect on the ligand localized S1.apprx..fwdarw.T1 intersystem crossing in the rare-earth-metal complexes with methyl salicylate.,J.Phys.Chem.,1985,89(26),5649-5654
64.Crosby G.A.,Whan R.E.,Alire R.M.,Intramolecular Energy Transfer in Rare Earth Chelates.Role of the Triplet State.,J.Chem.Phys.,1961,34(3),743-748
65.Weissman S.I.,Intramolecular Energy Transfer The Fluorescence of Complexes of Europium.,J.Chem.Phys.,1942,10(4),214-217
66.Crosby G.A.,Luminescent organic complexes of the rare earth metals.,Mol.Cryst.,1966,1(1),37
67.Sinha S.P.,Europium,Spinger-Verlag,New York,1967
68.Sinha S.P.,In Rao C.N.,Farraro J.R..Spectroscopy in Inorganic Chemistry,Vol 2,Academic Press.New York,1971
69.Horrocks Jr W.D.,Albin N.,Lathanide ion luminescence in coordination chemistry and biochemistry.,Prog.Inorg.Chem.,1984,31(1),1-104
70.张泉平,杜海燕,孙家跃,肖阳.,光致发光稀土有机配合物材料的研究进展及应用.,化工新型材料 2006,34(6),1-4
71.李文连,稀土有机配合物发光研究的新进展.,化学通报,1991,(8),1-9
72.李文连.,稀土有机电致发光研究进展.,中国稀土学报,1999,17(3),267-270
73.杨迟,杨燕生.杨池,杨燕生.,发光镧系超分子的设计及应用.,大学化学,1995,10(1),6-10
74.苏庆德,孙燕.,稀土有机配合物发光及光声光谱研究方法.,稀土,1997,18(6),56-72
75.苏锵.,稀土材料-21世纪的新材料,中国科学院院刊,1997,(2),79-81
76.高锦章,杨武,康敬万.溶液中镧系配合物光谱化学,电子科技大学出版社.成都,1995,.第一版。
77.Lv Y.,Zhang J.,Wang L.,Cao W.,Xu Z.,Enhanced electroluminescence of Eu~(3+)by Tb~(3+)in complexes Tb_(1-x)Eu_x(TTA)_3Dipy.,J.Lumin.,2008,128(1),117-122
78.Cao R,Liu S.,Xie L.,Pan Y.,Cao J.,Liu Y.,Influence of different site symmetries of Eu~(3+)centers on the luminescence properties of Anderson-based compounds.,Inorg.Chim.Acta,2008,361(7),2013-2018
79.Freeman J.J.,Crosby G.A.,SPECTRA AND DECAY TIMES OF THE LUMINESCENCES OBSERVED FROM CHELATED RARE EARTH IONS.,J.Phys.Chem.,1963,67(12),2717-2723
80.Dickins R.S.,Howard J.A.K.,Lehmann C.W.,Moloney J.,Parker D.,Peacock R.D.,Structural Rigidity and Luminescence of Chiral Lanthanide Tetraamide Complexes Based on 1,4,7,10-Tetraazacyclododecane.,Angew.Chem.Int.Ed.1997,36(5),521-523
81.Bolshoi D.B.,Meshkova S.B.,Topilova Z.M.,Lozinskil M.O.,Shapiro Yu.E.,Opt.Sepectrosc.1997,1401.
82.黄春辉.稀土配位化学[M].北京:科学技术出版社,北京,1997,363,第一版.
83.Carnall W.T.,Handbook of the Physics and Chmistry of Rare Earths,Vol.3,Northholland,Amsterdam,1979,171.
84.朱卫国,苑同锁,卢志云,谢明贵,有机金属螯合物电致发光材料的研究.,材料导报,2000,14(1),50-54
85.Renaud F.,Piguet C.,Bernardinelli G,Bunzli J.-C.G,Hopfgartner G,Nine-Coordinate Lanthanide Podates with Predetermined Structural and Electronic Properties:Facial Organization of Unsymmetrical Tridentate Binding Units by a Protonated Covalent Tripod.,J.Am.Chem.Soc.,1999,121(40),9326-9342
86.Sato S.,Wada.M.,Relations between intramolecular energy transfer efficiencies and triplet state energies in rare earth β-diketone chelates.,Bull.Chem.Soc.Jpn.,1970,43,1955-1959
87.Blasse G.,Dirksen G.J.,Sabbatini N.,Perathoner S.,Lehn J.M.,Alpha B.,Luminescence processes in[Tb.cntnd.bpy.bpy.bpy]~(3+)cryptate:a low-temperature solid-state study.,J.Phys.Chem.,1988,92(9),2419-2422
88.Crosby G.A.,Whan R.E.,Freeman J.J.,SPECTROSCOPIC STUDIES OF RARE EARTH CHELATES.,J.Phys.Chem.;1962;66(12);2493-2499
89.Khreis O.M.,Curry R.J.,Somertom M.,Gillin W.P.,Infrared Organic Light Emitting Devices Using Neodymium Tris-(8-hydrooxyquoline).,J.Appl.Phys.,2000,88,777-780
90.M.Kleinenman.J.Chem.Phys.,1964,41,4009
91.杨育华,蔡强,孟继武,侯尚公;水杨酸-Tb-(3+)(Gd-(3+))络合物的高效发光,发光学报,1991,12(2),67-70.
92.李博,顾镇南,林建华,YTaO_4:Gd,Eu体系光致发光中的能量传递,物理化学学报,1999,15(9),794-798.
93.吴根华,陈荣,张启运,KAlF_4:Ce,Tb磷光体的发光特性及Ce-(3+)对Tb-(3+)的敏化作用.,光谱学与光谱分析,1997,17(3),6-9.
94.Chen J.,Selvin P.R.,Lifetime- and Color-Tailored Fluorophores in the Micro- to Millisecond Time Regime.,J.Am.Chem.Soc.,2000,122(4),657-660
95.Buono-core G.E.,Li H.,Marciniak B.,Quenching of excited states by lanthanide ions and chelates in solution.,Coord.Chem.Rev.,1990,99,55-87
96.Elhabiri M.,Scopelliti R.,Bunzli J.-C.G.,Piguet C.,Lanthanide Helicates Self-Assembled in Water:A New Class of Highly Stable and Luminescent Dimetallic Carboxylates.,J.Am.Chem.Soc.,1999,121(46),10747-10762
97.Xu Q.,Fu L.,Li L.,Zhang H.,Xu R.,Preparation,characterization and photophysical properties of layered zirconium bis(monohydrogenphosphate)intercalated with rare earth complexes.,J.Mater.Chem.,2000,10(11),2532-2536
98.Li C.,Wang G.,Evans D.G.,Duan X.,Incorporation of rare-earth ions in Mg-Al layered double hydroxides:intercalation with an[Eu(EDTA)]~- chelate.,J.Solid State Chem.,2004,177(12),4569-4575
99.Gago S.,Pillinger M.,Sa Ferreira R.A.,Carlos L.D.,Santos T.M.,Goncalves I.S.,Immobilization of Lanthanide Ions in a Pillared Layered Double Hydroxide.,Chem.Mater.,2005,17(23),5803-5809
100.Kowal-Fouchard A.,Drot R.,Simoni E.,Marmier N.,Fromagec F.,Ehrhardtd J.-J.,Structural identi.eation of europium(Ⅲ)adsorption complexes on montmorillonite,New.J.Chem.,2004,28,864-869
101.蒋维,唐瑜,刘伟生,谭民裕,新型超分子复合发光材料-联吡啶氮氧化物铕配合物-蒙脱土的室温固相插层组装及发光性能,无机化学学报,2006,22(12),2235-2238
102.马继盛,张世民,漆宗能,胡友良,张树范,插层聚合聚丙烯-蒙脱土纳米复合材料的微观结构形态.,高等学校化学学报,2002,23(4),734-738
103.封禄田,刘子儒,王建枫,张巾玲,配位插层法制备酚醛树脂/蒙脱土纳米复合材料的性能研究,沈阳化工学院学报,2005,19(3),164-179
104.陈红,丁运生,查敏,张效敏,工业催化,蒙脱土负载[C_(14)mim]~+有机阳离子催化合成柠檬酸三丁酯.,2007,15(9),43-46
105.Borah M.,Ganguli J.N.,Dutta D.K.,Intersalation Reactions of Trisdiimine Metal Complexes with Montmorillonite Clay:A New Approach.,J.Colloid Interface Sci.,2001,233(2),171-179
106.雷立旭,忻新泉.,室温固相化学反应与固体结构.,化学通报,1997,(2),1-7
107.石恒真,陈建国,李敏,可膨胀层状硅酸盐粘土应用研究进展,化学通报,1998,(5),12
108.李海艳,李强.,有机染料-层状硅酸盐光活性纳米复合材料.,化学进展,2003,15(2),135-140
109.Fan X.,Xia C.,Advineula R.C.,Intercalation of polymerization initiators into montmorillonite nanopartiele platelets:free radical vs.anionic initiator clays.,Colloid Surface A,2003,219(1-3),75-86
110.Bongiovanni R.,Mazza D.,Ronchetti S.,Turcato E.A.,The influence of water on the intercalation of epoxy monomers in Na-montmorillonite.,J.Colloid Interface Sci.,2006, 296(2),515-519
111.徐如人,庞文琴.无机合成与制备化学,北京:高等教育出版社,2001,59
112.Kaupp G.,Schmeyers.,Boy.J.,Waste-free solid-state syntheses with quantitative yield.,Chemosphere,2001,43(1),55-61
113.唐新村,黄伯云,贺跃辉.,低热固相反应冷融熔机理和冷溶熔机理的证据.,无机化学学报,2005,21(1),12-14
114.Khaorapapong N.,Ogawa M.,Solid-state intercalation of 8-Hydroxyquinoline into Li(Ⅰ)-,Zn(Ⅱ)- and Mn(Ⅱ)-montmorillonites.,Appl.Clay Sci.,2007,35(1-2),31-38
1.Renaud F.,Piguet C.,Bernardinelli G.,Bunzli J.-C.G.,Hopfgartner G.Nine-Coordinate Lanthanide Podates with Predetermined Structural and Electronic Properties:Facial Organization of Unsymmetrical Tridentate Binding Units by a Protonated Covalent Tripod.,J.Am.Chem.Soc.,1999,121(40),9326-9342
2.莫尊里,高锦章,陈红,杨武,赵保卫.,新穴类大环配体.双环-N,N',N”-三-(1,4-苯基)-二-胺三乙酰胺和双环-N,N',N”-三-(1,2-苯基)-二-胺三乙酰胺的合成与表征.化学试剂,1999,21(3),131-132
3.Geary,W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122
4.Curtis N.F.,Curtis Y.M.,Some Nitrato-Amine Nickel(Ⅱ)Compounds with Monodentate and Bidentate Nitrate Ions.,Inorg.Chem.,1965,4(6),804-809
5.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
6.高锦章,杨武,康敬万,溶液中的镧系配合物光谱化学 pp:133-134
7.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.,Inorg.Chim.Acta.,1986,111:187-192.
8.Su C.-Y.Kang B.-S.,Liu H.-Q.,Wang Q.-G.,Chen Z.-N.,Lu Z.-L.,Tong Y.-X.,Mak T.C.W.,Luminescent Lanthanide Complexes with Encapsulating Polybenzimidazole Tripodal Ligands.,Inorg.Chem.,1999,38(7),1374-1375
9.Lowe M.P.,Rettig S.J.,Orvig C.,Highly Symmetric Group 13 Metal-Phosphinato Complexes:Multinuclear NMR(~(27)Al,~(31)P,~(71)Ga)Determination of Stability Constants at Low pH.J.Am.Chem.Soc.1996,118(43),10446-10456
10.(a)Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays: Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.2000,39(3),496-507
(b)Yang X.-P.,Su C.-Y.,Kang B.-S.,Feng X.-L.,Xiao W.-L.,Liu H.-Q.,Studies on lanthainde complexes of the tripodal ligand N,N-bis(2-benzimidazolylmethyl)-N-(2-pyridylmethyl)amine Crystal structures and luminescent properties.,J.Chem.Soc.,Dalton Trans.2000,(19),3253-3260
11.Aoki C.,Ishida T.,Nogami T.,Molecular Metamagnet[Ni(41mNNH)_2(NO_3)_2](4ImNNH=4-Imidazolyl Nitronyl Nitroxide)and the Related Compounds Showing Supramolecular H-Bonding Interactions.,Inorg.Chem.,2003,42(23),7616-7625
12.Abrahams B.F.,Jackson P.A.,Robson R.,A robust(10,3)-a network containing chiral micropores in the Ag~I coordination polymer of a bridging ligand that provides three bidentate metal-binding sites.Angew Chem Int Ed Engl,1998,37(19):2656-2659
13.Kepert C.J.,Rosseinsky M.J.,A porous chiral framework of coordinated 1,3,5-benzenetricarboxylate:quadruple interpenetration of the(10,3)-a network.Chem Commun,1998,(1):31-32
14.Carlucci.L,Ciani.G.,Proserpio D M,Sironi A.A three-dimensional 'racemate',interpenetration of two enantiomeric networks of the SrSi_2 topological type in the polymeric complex[Ag_2(2,3-Me_2pyz)_3][SbF_6]_2.Chem Commun,1996,(11):1393-1394
15.Abrahams B.F.,Batten S.R.,Hamit.H.,Hoskins B.F.,Robson R.,A wellsian 'three-dimensional' racemete:eight interpenetrating enantiomorphic(10,3)-a nets,four right and four left-handed.Chem Commun,1996,(11):1313-1314
16.Shattock T.R.,Vishweshwar P.,Wang Z.,Zaworotko M.J.,18-Fold Interpenetration and concomitant polymorphism in the 2:3 Co-crystal of trimesic acid and 1,2-bis(4-pyridyl)ethane.Cryst Growth Des,2005,5(6):2046-2049
17.Sumby C.J.,Hardie M.J.,Disentangling disorder in the three-dimensional coordination network of {Ag_3[Tris(2-pyridylmethyl)cyclotrigualacylene]_2}(PF_6)_3.Cryst Growth Des,2005,5(4):1321-1324
18.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P280-281
19.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p244-251
20.Roesky H.W.,Andruh M.,The interplay of coordinative,hydrogen bonding and π-πstacking interactions in sustaining supramolecular solid-state architectures.:A study case of bis(4-pyridyl)- and bis(4-pyridyl-N-oxide)tectons.Coord.Chem.Rev.,2003,236(1-2),91-119.
21.Zafiropoulos T.F.,Plakatouras J.C.,Perlepes S.P.,Preparation and properties of complexes of lanthanide(Ⅲ)salts with n-(2-pyddyl)pyridine-2'-carboxamide Polyhedron,1991,10(20-21),2405-2415
22.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p316-321
23.Neogi S.,Savitha G.,Bharadwaj P.K.,Structure of Discrete(H_2O)_(12)Clusters Present in the Cavity of Polymeric Interlinked Metallocycles of Nd(Ⅲ)or Gd(Ⅲ)and a Podand Ligand.,Inorg.Chem.,2004,43(13),3771-3773
1.Tsukube H.,Hosokubo M.,Wada M.,Shinoda S.,Tamiaki H.,Specific Recognition of Chiral Amino Alcohols via Lanthanide Coordination Chemistry:Structural Optimization of Lanthanide Tris(diketonates)toward Effective Circular Dichroism/Fluorescence Probing.Inog.Chem.2001,40(4),740-745
2.Hanaoka K.,Kikuchi K.,Kobayashi S.,Nagano T.,Time-Resolved Long-Lived Luminescence Imaging Method Employing Luminescent Lanthanide Probes with a New Microscopy System.J.Am.Chem.Soc.,2007,129(44),13502-13509
3.Kessler M.A.,Probing the Dissociation State of Acid-Base Indicators by Time-Resolved Lanthanide Luminescence:A Convenient Transduction Scheme for Optical Chemical Sensors.Anal.Chem.1999,71(8),1540-1543
4.Liu Z.,Jiang L.,Liang Z.,Gao Y.,Photo-switchable molecular devices based on metal-ionic recognition.,Tetra.Lett.,2005,46(5),885-887
5.酰胺型开链配体与稀土配合物的研究,张剑毕业论文(硕士)2003,p62
6.Geary W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122.
7.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
8.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p244-251
9.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.Inorg.Chim.Acta,1986,111,187-192.
10.Jeffrey G.A.,Maluszynska H.,Mitra.J.,Int.J.Biol.Macromol.,(1985),7,336-348
11.Steiner Th.,Cryst.Rev,(1996),6,1-57
12.Neogi S.,Savitha G.,Bharadwaj P.K.,Structure of Discrete(H_2O)_(12)Clusters Present in the Cavity of Polymeric Interlinked Metallocycles of Nd(Ⅲ)or Gd(Ⅲ)and a Podand Ligand.,Inorg.Chem.,2004,43(13),3771-3773.
1.Muller-Buschbaum K.,Gomez-Torres S.,Larsen P.,Wickleder C.,Crystal Engineering of Rare Earth Amides:~3_∞[Tb(Im)_3]@NH_3,a Homoleptic 3D Network Exhibiting Strong Luminescence.,Chem.Mater.,2007,19(4),655-659
2.Tzeng B.-C.,Huang Y.-C.,Chen B.-S.,Wu W.-M.,Lee S.-Y.,Lee G.-H.,Peng S.-M.,Crystal-Engineering Studies of Coordination Polymers and a Molecular-Looped Complex Containing Dipyridyl-Amide Ligands.,Inorg.Chem.,2007,46(1),186-195
3.Pallan P.S.,Von Matt P.,Wilds C.J.,Altmann K.-H.,Egli M.,RNA-Binding Affinities and Crystal Structure of Oligonucleotides Containing Five-Atom Amide-Based Backbone Structures.,Biochemistry,2006,45(26),8048-8057.
4.Videnova-Adrabinska V.,Coordination and supramolecular network entanglements of organodisulfonates.,Coord.Chem.Rev.,2007,251(15-16),1987-2016
5.Gunnlaugsson T.,Parker D.,Luminescent europium tetraazamacrocyclic complexes with wide range pH sensitivity.,Chem.Commun.,1998,511-512
6.Sarkar M.,Biradha K.,Crystal Engineering of Metal-Organic Frameworks Containing Amide Functionalities:Studies on Network Recognition,Transformations,and Exchange Dynamics of Guests and Anions Cryst.Growth Des.,2007,7(7),1318-1331
7.唐瑜,宋玉兰,蔡正洪,刘伟生,谭民裕.2,3-二(苄胺基甲酰基苯氧基-甲基)喹喔啉(L)稀土配合物的合成、表征及荧光性质研究.无机化学学报,2004,20(10),1233-1236
8.Dahrouch M.R.,Jara P.,Mendez L.,Portilla Y.,Abril D.,Alfonso,G.,Chavez I.,Manriquez J.M.,Riviere-Baudet M.,Riviere P.,Castel A.,Rouzaud J.,Gornitzka,H.,An Effective and Selective Route to 1,5-Dihydropolyalkylated s-Indacenes:Characterization of Their Mono- and Dianions by Silylation.Structure of trans-1,5-Bis(trimethylsilyl)-2,6-diethyl-4,8-dimethyl-s-indacene.,Organometallics,2001,20(26),5591-5597.
9.Li J.,Liu D.,Li Y.,Lee C.-S.,Kwong H.-L.,Lee S.,A High Tg Carbazole-Based Hole-Transporting Material for Organic Light-Emitting Devices.,Chem.Mater.,2005,17(5),1208-1212.
10.Geary W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122
11.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
12.Curtis N.F.,Curtis Y.M.,Some Nitrato-Amine Nickei(Ⅱ)Compounds with Monodentate and Bidentate Nitrate Ions.,Inorg.Chem.,1965,4(6),804-809
13.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P280-281
14.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.Inorg.Chim.Acta.,1986,111,187-192
15.Fan J.,Sui B.,Okamura T-a.,Sun W.-Y.,Tang W.-X.,Ueyamab N.,Synthesis,structures and properties of two-dimensional honeycomb and stepwise networks from self-assembly of tripodal ligand 1,3,5-tris(imidazol-1-ylmethyl)-2,4,6-trimethylbenzene with metal salts.,J.Chem.Soc.,Dalton Trans.,2002,3868-3873
16.Aakeroy C.B.,Beatty A.M.,Helfrich B.A.,Two-fold interpenetration of 3-D nets assembled via three-co-ordinate silver(I)ions and amide-amide hydrogen bonds.,J.Chem.Soc.,Dalton Trans.,1998,1943-1945
17.Xu Z.,Kiang Y.-H.,Lee S.,Lobkovsky E.B.,Emmott N.,Hydrophilic-to-Hydrophobic Volume Ratios as Structural Determinant in Small-Length Scale Amphiphilic Crystalline Systems:Silver Salts of Phenylacetylene Nitriles with Pendant Oligo(ethylene Oxide)Chains.,J.Am.Chem.Soc.,2000,122(35),8376-8391
18.Wells A F.,Three-dimensional nets and polyhedra,Wiley-Interscience,New York,1977,p56-118
19.Ohrstrom L.,Larsson K.,What kinds of three-dimensional nets are possible with tris-chelated metal complexes as building blocks? J Chem Soc Dalton Trans,2004,(3),347-353
20.Shu M.H,Tu C.L,Xu W.D.,Jin H.B.,Sun J.,Reversible anion exchanges of porous metal-organic frameworks:syntheses and structures of silver complexes with novel rigid tripodal nitrogen ligands.Cryst Growth Des,2006,6(8),1890-1896
21.Abrahams B.F.,Jackson P.A.,Robson R.,A robust(10,3)-a network containing chiral micropores in the Ag~1 coordination polymer of a bridging ligand that provides three bidentate metal-binding sites.Angew Chem Int Ed Engl,1998,37(19),2656-2659
22.Kepert C.J.,Rosseinsky M.J.,A porous chiral framework of coordinated 1,3,5-benzenetricarboxylate:quadruple interpenetration of the(10,3)-a network.Chem Commun,1998,(1),31-32
23.Carlucci L.,Ciani G.,Proserpio D.M.,Sironi A.,A three-dimensional 'racemate', interpenetration of two enantiomeric networks of the SrSi_2 topological type in the polymeric complex[Ag_2(2,3-Me_2pyz)_3][SbF_6]_2.Chem Commun,1996,(11),1393-1394
24.Abrahams B.F.,Batten S.R.,Hamit H.,Hoskins B.F.,Robson R.,A wellsian 'three-dimensional' racemete:eight interpenetrating enantiomorphic(10,3)-a nets,four right and four left-handed.Chem Commun,1996,(11),1313-1314
25.Shattock T.R.,Vishweshwar P.,Wang Z.,Zaworotko M.J.,18-Fold Interpenetration and concomitant polymorphism in the 2:3 Co-crystal of trimesic acid and 1,2-bis(4-pyridyl)ethane.Cryst Growth Des,2005,5(6),2046-2049
26.Sumby C.J.,Hardie M.J.,Disentangling disorder in the three-dimensional coordination network of {Ag_3[Tris(2-pyridylmethyl)cyclotriguaiacylene]_2}(PF_6)_3.Cryst Growth Des,2005,5(4),1321-1324
1.Sabbatini N.,Guardigli M.,Lehn J.M.,Luminescent lanthanide complexes as photochemical supramolecular devices.,Coord.Chem.Rev.,1993,123(1-2),201-228
2.黄春辉.稀土配位化学[M].北京:科学技术出版社,1997,p363
3.Carnall W.T.,Handbook of the Physics and Chmistry of Rare Earths,Vol.3,Northholland,Amsterdam,1979,p171
4.Richardson F.S.,Terbium(Ⅲ)and europium(Ⅲ)ions as luminescent probes and stains for biomolecular systems.Chem.Rev.,1982,82(5),541-552
5.Hu X.,Cui S.,Yan L.,Yang R.D.,Synthesis,Characterization and Fluorescence of Rare earth Nitrate Complexes with Tdaza-crown Ether Derivative.,J.Rare Earths.2003,21(3),395-397.
6.苏锵,稀土化学.,第一版,郑州.河南技术出版社,1993,p310.
7.Martti L.,Hard T.,Veli-Matti M.,Cristina M.,Juan C.R.,Jouko K.,Correlation between the lowest triplet state energy level of the ligand and lanthanide(Ⅲ)luminescence quantum yield.,J.Lumin.,1997,75:149-169
8.Dexter D.L.,A Theory of Sensitized Luminescence in Solids.,J.Chem.Phys.,1953,21,836-850
9.Moore J.H.,Sato Y.,Staley S.W.,Energies and relative cross sections of singlet-triplet transitions in methyl-substituted 1,3-butadienes by ion-impact spectroscopy1965,69(3),1092-1095
10.Bassett,A.P.,Magennis,S.W.,Glover,P.B.,Lewis,D.J.,Spencer,N.,Parsons,S.,Williams,R.M.,De Cola,L.,Pikramenou,Z.,Highly Luminescent,Triple- and Quadruple-Stranded,Dinuclear Eu,Nd,and Sm(Ⅲ)Lanthanide Complexes Based on Bis-Diketonate Ligands.,J.Am.Chem.Soc.,2004;126(30);9413-9424.
11.Latva M.,Takalo H.,Mukkala V.-M.,Matachescu C.,Rodriguez-Ubis J.C.,Kankare J.,Correlation between the lowest triplet state energy level of the ligand and lanthanide(Ⅲ)luminescence quantum yield.,J.Lumin.1997,75(2),149-169
12.Blasse G.,Dirksen G.J.,Sabbatini N.,Perathoner S.,Lehn J.M.,Alpha B.,Luminescence processes in[Tb.cntnd.bpy.bpy.bpy]~(3+)cryptate:a low-temperature solid-state study.,J.Phys.Chem.,1988,92(9),2419-2422
13.Crosby G.A.,Whan R.E.,Freeman J.J.,SPECTROSCOPIC STUDIES OF RARE EARTH CHELATES.,J.Phys.Chem.;1962;66(12);2493-2499
14.闫冰,张洪杰,王淑彬,倪嘉瓒.Photophysical Properties of Rare Earth Complexes with 3,4 furandicarboxylic Acid and 1,10 phenanthroline中国稀土学报.1998,16(4),375-378
15.Sato S.,Wada.M.,Relations between intramolecular energy transfer efficiencies and triplet state energies in rare earth β-diketone chelates.,Bull.Chem.Soc.Jpn.,1970,43,1955-1959
1.Pinnavaia T.J.,Intercalated Clay Catalysts.,1983,220(4595),365-371
2.林鸿福,林峰,袁尉顺.制备纳米复合材料的天然矿物--蒙脱石.,化工新型材料,2001,29(4),20-27
3.沈家骢.超分子层状结构-组装与功能,北京:科学出版社,2003,p163
4.Borah M.,Ganguli J.N.,Dutta D.K.,Intersalation Reactions of Trisdiimine Metal Complexes with Montmodlionite Clay:A New Approach.,J.Colloid Interface Sci.,2001,233(2),171-179
5.Xu Q.H.,Fu L.S.,Li L.S.,Zhang H.J.,Xu R.R.,Preparation,charactedsation and photophysical properties of layered compounds zironium bis(Monohydrogenphosphate)intercalated rare earth complexes.,J.Mater.Chem.,2000,10,2532-2536
6.Ghosh P.K.,Bard A.J.,Photochemistry of tris(2,2'-bipyridyl)(ruthenium(Ⅱ)in colloidal clay suspensions.,J.Phys.Chem.,1984,88(23),5519-5526
7.Figueras F.,Pillared clays as catalysts.,Catal.Rev.Sci.Eng.,1988,30(3),457-459
8.Lakowicz J.R.,Principles of Fluorescence Spectroscopy,Plenum Press,New York,1983
2.Pederson C.J.,Cyclic polyethers and their complexes with metal salts.,J.Am.Chem.Soc.1967,89,7017-7036
3.Cram D.J.,Cram J.M.,Host-Guest Chemistry:Complexes between organic compounds simulate the substrate selectivity of enzymes.,Science,1974,183,803-809
4.Lehn J.M.,Supramolecular Chemistry- Scope and perspectives molecules,Supermolecules,and molecular devices(Nobel Lecture).,Angew.Chem.Int.Ed.,1988,27,89-112
5.Kumara Swamy K.C.,Kumaraswamy S.,Kommana P.,Very Strong C-H…O,N-H…O,and O-H…O Hydrogen Bonds Involving a Cyclic Phosphate.,J.Am.Chem.Soc.,2001,123(50),12642-12649
6.Demeshko S.,Dechert S.,Meyer F.,Anion-π Interactions in a Carousel Copper(Ⅱ)-Triazine Complex.,J.Am.Chem.Soc.,2004,126(14),4508-4509
7.Vilar R.,Anion-templated synthesis.,Angew.Chem.Int.Ed.,2003,42(13),1460-1477
8.Structural determinants of water permeation through aquaporin-1.,Murata K.,Mitsuoka K.,Hirai T.,Walz T.,Agrek P.,Heymann J.B.,Engel A.,Fujiyoshi Y.,Nature,2000,407,599-605
9.Gao T.,Yan P.-F.,Li G.-M.,Hou G.-F.,Gao J.-S.,N,N'-Ethylene-bis(3-methoxysalicylideneimine)mononuclear(4f)and heterodinuclear (3d-4f)metal complexes:Synthesis,crystal structure and luminescent properties.,Inorg.Chim.Acta,2008,361(7),2051-2058
10.Tamboura F.B.,Haba P.M.,Gaye M.,Sall,A.S.Barry A.H.,Jouini T.,Structural studies of bis-(2,6-diacetylpyridine-bis-(phenylhydrazone))and X-ray structure of its Y(Ⅲ),Pr(Ⅲ),Sm(Ⅲ)and Er(Ⅲ)complex.,Polyhedron,2004,23(7),1191-1197
11.Wang F.-Q.,Zheng X.-J.,Wan Y.-H.,Wang K.-Z.,Jin L.-P.,Architecture of zero-,one-,two- and three-dimensional structures based on metal ions and pyrazine-2,6-dicarboxylic acid.,Polyhedron,2008,27(2),717-726
12.Dalgarno S.J.,Hardie M.J.,Atwood J.L.,Warrenc J.E.,Raston C.L.,A complex 3D 'wavy brick wall' coordination polymer based on p-sulfonatocalix arene.,New J.Chem.,2005(29),649-652
13.Dong Y.-B.,Xu H.-X.,Ma J.-P.,Huang R.-Q.,Silver(Ⅰ)Coordination Polymers Based on A Nano-Sized Bent Bis(3-acetylenylpbenyl-(4-cyanophenyl))oxadiazole Ligand:The Role of Ligand Isomerism and the Templating Effect of Polyatomic Anions and Solvent Intermediates.,Inorg.Chem.2006,45(8),3325-3343
14.Shavaleev N.M.,Bell Z.R.,Accorsi G.,Ward M.D.,Syntheses and structures of mononuclear {Re(CO)_3Cl(NN)} 'complex ligands' with a pendant imino-pyridine binding site,and preparation of some heterodinuclear Re(Ⅰ)-lanthanide(Ⅲ)complexes Inorg.Chim.Acta,2003,351,159-166
15.Caravan P.,Hedlund T.,Liu S.,Sjoeberg S.,Orvig C.,Potentiometric,Calorimetric,and Solution NMR Studies of a Tridentate Ligand Which has a Marked Preference for Formation of Bis(ligand)versus Mono(ligand)Lanthanide Complexes and Which Exhibits High Selectivity for Heavier Lanthanides.,J.Am.Chem.Soc.,1995,117(45),11230-11238
16.Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays:Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.,2000,39(3),496-507
17.Yang X.-P.,Kang B.-S.,Wong W.-K.,Su C.-Y.,Liu H.-Q.,Syntheses,Crystal Structures,and Luminescent Properties of Lanthanide Complexes with Tripodal Ligands Bearing Benzimidazole and Pyridine Groups.,Inorg.Chem.,2003,42(1),169-179
18.Wada A.,Honda Y.,Yarnaguchi S.,Nagatomo S.,Kitagawa T.,Jitsukawa K.,Masuda H.,Steric and Hydrogen-Bonding Effects on the Stability of Copper Complexes with Small Molecules.,Inorg.Chem.,2004,43(18),5725-5735
19.Mandon D.,Nopper A.,Litrol T.,Goetz S.,Tridentate Coordination of Monosubstituted Derivatives of the Tris(2-pyridylmethyl)amine Ligand to FeCl_3:Structures and Spectroscopic Properties of((2-Bromopyridyl)methyl)bis-(2-pyridylmethyl)amine Fe~ⅢCl_3and(((2-p- Methoxyphenyl)pyridyl)methyl)Bis(2-pyridyl-methyl)]amine Fe~ⅢCl_3 and Comparison with the Bis(2-pyridylmethyl)]amine Fe~ⅢCl_3 Complex.,Inorg.Chem.,2001,40(18),4803-4806
20.Velusamy M.,Mayilmurugan R.,Palaniandavar M.,Iron(Ⅲ)Complexes of Sterically Hindered Tetradentate Monophenolate Ligands as Functional Models for Catechol 1,2-Dioxygenases:The Role of Ligand Stereoelectronic Properties.,Inorg.Chem.,2004,43(20),6284-6293
21.Paul S.,Batik A.K.,Pang S.M.,Kar S.K.,Novel Copper(Ⅱ)Induced Formation of a Porphyrinogen Derivative:X-ray Structural,Spectroscopic,and Electrochemical Studies of Porphyrinogen Complexes of Cu(Ⅱ)and Co(Ⅲ)Complex of a Trispyrazolyl Tripodal Ligand.,Inorg.Chem.,2002,41(22),5803-5809
22.Hammes B.S.,Kieber-Emmons M.T.,Sommer R.,Rheingold A.L.,Modulating the Reduction Potential of Mononuclear Cobalt(Ⅱ)Complexes via Selective Deprotonation of Tris[(2-benzimidazolyl)methyl]amine.,Inorg.Chem.,2002,41(6),1351-1353
23.Mizuno M.,Hayashi H.,Fujinami S.,Furutachi H.,Nagatomo S.,Otake S.,Uozumi K.,Suzuki M.,Kitagawa T.,Ligand Effect on Reversible Conversion between Copper(Ⅰ)and Bis(μ-oxo)dicopper(Ⅲ)Complex with a Sterically Hindered Tetradentate Tripodal Ligand and Monooxygenase Activity of Bis(μ-oxo)dicopper(Ⅲ)Complex.,Inorg.Chem.,2003,42(25),8534-8544
24.Sunatsuki Y.,Ohta H.,Kojima M.,Ikuta Y.,Goto Y.,Matsumoto N.,Iijima S.,Akashi H., Kalzaki S.,Dahan F.,Tuchagues J.-P.,Supramolecular Spin-Crossover Iron Complexes Based on Imidazole-Imidazolate Hydrogen Bonds.,Inorg.Chem.,2004,43(14),4154-4171
25.Tor Y.,Libman J.,Shanzer.A.,Biomimetic ferric ion carders.Chiral ferdchrome analogs.,J.Am.Chem.Soc.,1987,109(21),6518-6519
26.Dayan I.,Libman J.,Shanzer A.,Felder C.E.,Lifson.S.,Regulation of molecular conformation of chiral tripodal structures by calcium-cation binding.,J.Am.Chem.Soc.,1991,113(9),3431-3439
27.Dayan I.,Libman J.,Agi Y.,Shanzer.A.,Chiral siderophore analogs:ferrichrome.,Inorg.Chem.,1993,32(8),1467-1475
28.卢会杰,尹明彩,樊耀亭,侯红卫,吴养洁.三脚架结构化合物及其配合物研究进展,无机化学学报,200l,17(4),478-488
29.Mealli C.,Ghilardi C.A.,Orlandini A.,Structural flexibility and bonding capabilities of the ligand np_3 toward the transition metals.,Coord.Chem.Rev.,1992,120,361-387
30.Clark K.A.,George T.A.,Trigonal-Bipyrarnidal Tin(Ⅳ)Complexes Containing Tetradentate Tripodal Tristhiolatophosphine Ligands:Synthesis,Characterization,Crystal Structure,and Transmetalation Reactions.,Inorg.Chem.,2005,44(2),416-422
31.Block E.,Ofori-Okai G.,Zubieta J.,2-Phosphino- and 2-phosphinylbenzenethiols:new ligand types.,J.Am.Chem.Soc.,1989,111(6),2327-2329
32.Vries N.D.,Cook J.,Jones A.G.,Davison A.,Technetium(Ⅲ)complexes with the tetradentate "umbrella" ligand tris(o-mereaptophenyl)phosphinate:x-ray structural characterization of Te(P(o-C6H4S)3)(CNC3H7)and Te(P(o-C6H4S)3)(CNC3H7)2.,Inorg.Chem.,1991,30(12),2662-2665
33.Xu Z.,Read P.W.,Hibbs D.E.,Hursthouse M.B.,Abdul Malik K.M.,Patrick B.O.,Rettig S.J.,Seid M.,Summers D.A.,Pink M.,Thompson R.C.,Orvig C.,Coaggregation of Paramagnetie d- and f-Block Metal Ions with a Podand-Framework Amine Phenol Ligand.,Inorg.Chem.,2000,39(3),508-516
34.Caravan P.,Orvig C.,Tripodal Aminophenolate Ligand Complexes of Aluminum(Ⅲ),Gallium(Ⅲ),and Indium(Ⅲ)in Water.,Inorg.Chem.,1997,36(2),236-248
35.Lowe M.P.,Caravan P.,Rettig S.J.,Orvig C.,Tightening the Hydrophobic Belt:Effects of Backbone and Donor Group Variation on Podand Ligand Complexes of the Lanthanides.,Inorg.Chem.,1998,37(7),1637-1647
36.Liu S.,Wong E.,Karunaratne V.,Rettig S.J.,Orvig C.,Highly flexible chelating ligands for Group 13 metals:design and synthesis of hexadentate(N3O3)tripodal amine phenol ligand complexes of aluminum,gallium,and indium.,Inorg.Chem.,1993,32(9),1756-1765
37.Liu S.,Wong E.,Rettig S.J.,Orvig C.,Hexadentate N3O3 amine phenol ligands for Group 13 metal ions:evidence for intrastrand and interstrand hydrogen-bonds in polydentate tripodal amine phenols.,Inorg.Chem.,1993,32(20),4268-4276
38.Armaroli N.,Accorsi G.,Barigelletti F.,Couchman S.M.,Fleming,J.S.,Harden N.C.,Jeffery J.C.,Mann K.L.V.,McCleverty J.A.,Rees L.H.,Starling S.R.,Ward M.D.,Structural and Photophysical Properties of Mononuclear and Dinuclear Lanthanide(Ⅲ)Complexes of Multidentate Podand Ligands Based on Poly(pyrazolyl)borates.,Inorg.Chem.,1999,38(25),5769-5776
39.Reeves Z.R.,Mann K.L.V.,JeVery J.C.,McCleverty J.A.,Ward M.D.,Barigelletti F.,Armaroli N.Lanthanide complexes of a new sterically hindered potentially hexadentate podand ligand based on a tris(pyrazolyl)borate core;crystal structures,solution structures and luminescence properties.,J.Chem.Soc.,Dalton Trans.,1999,349-355
40.Davies G.M.,Aarons R.J.,Motson G.R.,Jeffery J.C.,Adams H.,Faulkner S.,Ward M.D.,Structural and near-IR photophysical studies on ternary lanthanide complexes containing poly(pyrazolyl)borate and 1,3-diketonate ligands.,DaltonTrans.,2004,1136-1144
41.Careri M.,Elviri L.,Lanfranchi M.,Marchio L.,Mora C.,Pellinghelli M.A.,Versatile Ligand Behavior of Hydrotris(4-ethyl-3-methyl-5-thioxo-1,2,4-triazolyl)borate.Syntheses and Crystal Structures of Cu(Ⅰ)and Bi(Ⅲ)Complexes.,Inorg.Chem.,2003,42(6),2109-2114
42.Dodds C.A.,Lehmann M.-A.,Ojo J.F.,Reglinski J.,Spicer M.D.,Cobalt Half-Sandwich,Sandwich,and Mixed Sandwich Complexes with Soft Tripodal Ligands.,Inorg.Chem.,2004,43(16),4927-4934
43.Gorden A.E.V.,Xu J.,Raymond K.N.,Durbin P.,Rational Design of Sequestering Agents for Plutonium and Other Actinides.,Chem.Rev.,2003,103(11),4207-4282
44.Schumann H.,Meese-Marktscheffel J.A.,Esser L.,Synthesis,Structure,and Reactivity of Organometallic.pi.-Complexes of the Rare Earths in the Oxidation State Ln~(3+)with Aromatic Ligands.,Chem.Rev.,1995,95(4),865-986
45.Armaroli N.,Acoorsi G.,Barigelletti F.,Couchman S.M.,Fleming J.S.,Harden N.C.,Jeffery J.C.,Mann K.L.V.,McCleverty J.A.,Rees L.H.,Starling S.R.,Ward M.D.,Structural and Photophysical Properties of Mononuclear and Dinuclear Lanthanide(Ⅲ)Complexes of Multidentate Podand Ligands Based on Poly(pyrazolyl)borates.,Inorg.Chem.,1999,38(25),5769-5776
46.Yang X.-P.,Kang B.-S.,Wong W.-K.,Su C.-Y.,Liu H.-Q.,Syntheses,Crystal Structures,and Luminescent Properties of Lanthanide Complexes with Tripodal Ligands Bearing Benzimidazole and Pyridine Groups.,Inorg.Chem.,2003,42(1),169-179
47.Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays:Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.,2000,39(3),496-507
48.Reeves Z.R.,Mann K.L.V.,JeVery J.C.,McCleverty J.A.,Ward M.D.,Barigelletti F., Armaroli N., Lanthanide complexes of a new sterically hindered potentially hexadentate podand ligand based on a tris(pyrazolyl)borate core; crystal structures, solution structures and luminescence properties., J. Chem. Soc., Dalton Trans., 1999,349-355
49. Davies G. M., Aarons R. J., Motson G. R., Jeffery J. C., Adams, H. Faulkner S., Ward M. D., Structural and near-IR photophysical studies on ternary lanthanide complexes containing poly(pyrazolyl)borate and 1,3-diketonate ligands., Dalton Trans., 2004, 1136-1144
50. Kanesato M., Mizukami S., Houjou H., Tokuhisa H., Koyama E., Nagawa Y., Comparison of the bond lengths for the lanthanide complexes of tripodal heptadentate ligands., J. Alloy. Compd., 2004,374(1-2), 307-310
51. Heck R., Marsura A., A new symmetrically modified a-cyclodextrin tripode: selective metal complexation and fluorescence properties., Tetrahedron Letter, 2004, 45(2), 281-284
52. Horike S., Matsuda R., Tanaka D., Mizuno M., Endo K., Kitagawa S., Immobilization of Sodium Ions on the Pore Surface of a Porous Coordination Polymer., J. Am. Chem. Soc., 2006,128(13), 4222-4223
53. Su C.-Y., Cai Y.-P., Chen C.-L., Smith M. D., Kaim W., Zur Loye H.-C., Ligand-Directed Molecular Architectures: Self-Assembly of Two-Dimensional Rectangular Metallacycles and Three-Dimensional Trigonal or Tetragonal Prisms., J. Am. Chem. Soc., 2003,125(28),8595-8613
54. Wang S., Xing H., Li Y., Bai J., Pan Y., Scheer M., You X., 2D and 3D Cadmium(II) Coordination Polymers from a Flexible Tripodal Ligand of 1,3,5-Tris(carboxymethoxy)benzene and Bidentate Pyridyl-Containing Ligands with Three-, Eight- and Ten-Connected Topologies., Eur. J. Inorg. Chem., 2006, 2006(15), 3041-3053
55. Rosa D. T., Krause Bauer J. A., Baldwin M. J., Structural and Spectroscopic Studies of the Versatile Coordination Chemistry of the Chiral Ligand N,N-Bis(1-propan-2-onyl oxime)-L-methionine N'-Methylamide with Ni~(II) and Zn~(II)., lnorg. Chem., 2001, 40(7), 1606-1613
56. Reger D. L., Semeniuc R. F., Smith M. D., Synthesis of Open and Closed Metallacages Using Novel Tripodal Ligands: Unusually Stable Silver(I) Inclusion Compound., Inorg. Chem., 2003,42(25), 8137-8139
57. Yam V. W. W., Lo K. K. W., Recent advances in utilization of transition metal complexes and lanthanides as diagnostic tools., Coord. Chem. Rev., 1999,184(1), 157-240
58. Lauffer R. B., Paramagnetic metal complexes as water proton relaxation agents for NMR imaging: theory and design., Chem. Rev., 1987,87(5), 901-927
59. Vigato P. A., Tamburini S., Bertolo L., The development of compartmental macrocyclic Schiff bases and related polyamine derivatives., Coord. Chem. Rev., 2007, 251(11-12), 1311-1492
60.Shibasaki M.,Sasai H.,Arai T.,Asymmetric Catalysis with Heterobimetallic Compounds.,Angew.Chem.Int.Ed.Engl.,1997,36(12),1236-1256
61.Sabbatini N.,Guardigli M.,Lehn J.M.,Luminescent lanthanide complexes as photochemical supramolecular devices.,Coord.Chem.Rev.,1993,123(1-2),201-228
62.Suarez S.,Imbert D.,Gumy F.,Piguet C.,Bunzli J.-C.G.,Metal-Centered Photoluminescence as a Tool for Detecting Phase Transitions in Eu~Ⅲ- and Tb~Ⅲ-Containing Metallomesogens.,Chem.Mater.,2004;16(17),3257-3266
63.Tobita S.j.,Arakawa M.,Tanaka.I.,The paramagnetic metal effect on the ligand localized S1.apprx..fwdarw.T1 intersystem crossing in the rare-earth-metal complexes with methyl salicylate.,J.Phys.Chem.,1985,89(26),5649-5654
64.Crosby G.A.,Whan R.E.,Alire R.M.,Intramolecular Energy Transfer in Rare Earth Chelates.Role of the Triplet State.,J.Chem.Phys.,1961,34(3),743-748
65.Weissman S.I.,Intramolecular Energy Transfer The Fluorescence of Complexes of Europium.,J.Chem.Phys.,1942,10(4),214-217
66.Crosby G.A.,Luminescent organic complexes of the rare earth metals.,Mol.Cryst.,1966,1(1),37
67.Sinha S.P.,Europium,Spinger-Verlag,New York,1967
68.Sinha S.P.,In Rao C.N.,Farraro J.R..Spectroscopy in Inorganic Chemistry,Vol 2,Academic Press.New York,1971
69.Horrocks Jr W.D.,Albin N.,Lathanide ion luminescence in coordination chemistry and biochemistry.,Prog.Inorg.Chem.,1984,31(1),1-104
70.张泉平,杜海燕,孙家跃,肖阳.,光致发光稀土有机配合物材料的研究进展及应用.,化工新型材料 2006,34(6),1-4
71.李文连,稀土有机配合物发光研究的新进展.,化学通报,1991,(8),1-9
72.李文连.,稀土有机电致发光研究进展.,中国稀土学报,1999,17(3),267-270
73.杨迟,杨燕生.杨池,杨燕生.,发光镧系超分子的设计及应用.,大学化学,1995,10(1),6-10
74.苏庆德,孙燕.,稀土有机配合物发光及光声光谱研究方法.,稀土,1997,18(6),56-72
75.苏锵.,稀土材料-21世纪的新材料,中国科学院院刊,1997,(2),79-81
76.高锦章,杨武,康敬万.溶液中镧系配合物光谱化学,电子科技大学出版社.成都,1995,.第一版。
77.Lv Y.,Zhang J.,Wang L.,Cao W.,Xu Z.,Enhanced electroluminescence of Eu~(3+)by Tb~(3+)in complexes Tb_(1-x)Eu_x(TTA)_3Dipy.,J.Lumin.,2008,128(1),117-122
78.Cao R,Liu S.,Xie L.,Pan Y.,Cao J.,Liu Y.,Influence of different site symmetries of Eu~(3+)centers on the luminescence properties of Anderson-based compounds.,Inorg.Chim.Acta,2008,361(7),2013-2018
79.Freeman J.J.,Crosby G.A.,SPECTRA AND DECAY TIMES OF THE LUMINESCENCES OBSERVED FROM CHELATED RARE EARTH IONS.,J.Phys.Chem.,1963,67(12),2717-2723
80.Dickins R.S.,Howard J.A.K.,Lehmann C.W.,Moloney J.,Parker D.,Peacock R.D.,Structural Rigidity and Luminescence of Chiral Lanthanide Tetraamide Complexes Based on 1,4,7,10-Tetraazacyclododecane.,Angew.Chem.Int.Ed.1997,36(5),521-523
81.Bolshoi D.B.,Meshkova S.B.,Topilova Z.M.,Lozinskil M.O.,Shapiro Yu.E.,Opt.Sepectrosc.1997,1401.
82.黄春辉.稀土配位化学[M].北京:科学技术出版社,北京,1997,363,第一版.
83.Carnall W.T.,Handbook of the Physics and Chmistry of Rare Earths,Vol.3,Northholland,Amsterdam,1979,171.
84.朱卫国,苑同锁,卢志云,谢明贵,有机金属螯合物电致发光材料的研究.,材料导报,2000,14(1),50-54
85.Renaud F.,Piguet C.,Bernardinelli G,Bunzli J.-C.G,Hopfgartner G,Nine-Coordinate Lanthanide Podates with Predetermined Structural and Electronic Properties:Facial Organization of Unsymmetrical Tridentate Binding Units by a Protonated Covalent Tripod.,J.Am.Chem.Soc.,1999,121(40),9326-9342
86.Sato S.,Wada.M.,Relations between intramolecular energy transfer efficiencies and triplet state energies in rare earth β-diketone chelates.,Bull.Chem.Soc.Jpn.,1970,43,1955-1959
87.Blasse G.,Dirksen G.J.,Sabbatini N.,Perathoner S.,Lehn J.M.,Alpha B.,Luminescence processes in[Tb.cntnd.bpy.bpy.bpy]~(3+)cryptate:a low-temperature solid-state study.,J.Phys.Chem.,1988,92(9),2419-2422
88.Crosby G.A.,Whan R.E.,Freeman J.J.,SPECTROSCOPIC STUDIES OF RARE EARTH CHELATES.,J.Phys.Chem.;1962;66(12);2493-2499
89.Khreis O.M.,Curry R.J.,Somertom M.,Gillin W.P.,Infrared Organic Light Emitting Devices Using Neodymium Tris-(8-hydrooxyquoline).,J.Appl.Phys.,2000,88,777-780
90.M.Kleinenman.J.Chem.Phys.,1964,41,4009
91.杨育华,蔡强,孟继武,侯尚公;水杨酸-Tb-(3+)(Gd-(3+))络合物的高效发光,发光学报,1991,12(2),67-70.
92.李博,顾镇南,林建华,YTaO_4:Gd,Eu体系光致发光中的能量传递,物理化学学报,1999,15(9),794-798.
93.吴根华,陈荣,张启运,KAlF_4:Ce,Tb磷光体的发光特性及Ce-(3+)对Tb-(3+)的敏化作用.,光谱学与光谱分析,1997,17(3),6-9.
94.Chen J.,Selvin P.R.,Lifetime- and Color-Tailored Fluorophores in the Micro- to Millisecond Time Regime.,J.Am.Chem.Soc.,2000,122(4),657-660
95.Buono-core G.E.,Li H.,Marciniak B.,Quenching of excited states by lanthanide ions and chelates in solution.,Coord.Chem.Rev.,1990,99,55-87
96.Elhabiri M.,Scopelliti R.,Bunzli J.-C.G.,Piguet C.,Lanthanide Helicates Self-Assembled in Water:A New Class of Highly Stable and Luminescent Dimetallic Carboxylates.,J.Am.Chem.Soc.,1999,121(46),10747-10762
97.Xu Q.,Fu L.,Li L.,Zhang H.,Xu R.,Preparation,characterization and photophysical properties of layered zirconium bis(monohydrogenphosphate)intercalated with rare earth complexes.,J.Mater.Chem.,2000,10(11),2532-2536
98.Li C.,Wang G.,Evans D.G.,Duan X.,Incorporation of rare-earth ions in Mg-Al layered double hydroxides:intercalation with an[Eu(EDTA)]~- chelate.,J.Solid State Chem.,2004,177(12),4569-4575
99.Gago S.,Pillinger M.,Sa Ferreira R.A.,Carlos L.D.,Santos T.M.,Goncalves I.S.,Immobilization of Lanthanide Ions in a Pillared Layered Double Hydroxide.,Chem.Mater.,2005,17(23),5803-5809
100.Kowal-Fouchard A.,Drot R.,Simoni E.,Marmier N.,Fromagec F.,Ehrhardtd J.-J.,Structural identi.eation of europium(Ⅲ)adsorption complexes on montmorillonite,New.J.Chem.,2004,28,864-869
101.蒋维,唐瑜,刘伟生,谭民裕,新型超分子复合发光材料-联吡啶氮氧化物铕配合物-蒙脱土的室温固相插层组装及发光性能,无机化学学报,2006,22(12),2235-2238
102.马继盛,张世民,漆宗能,胡友良,张树范,插层聚合聚丙烯-蒙脱土纳米复合材料的微观结构形态.,高等学校化学学报,2002,23(4),734-738
103.封禄田,刘子儒,王建枫,张巾玲,配位插层法制备酚醛树脂/蒙脱土纳米复合材料的性能研究,沈阳化工学院学报,2005,19(3),164-179
104.陈红,丁运生,查敏,张效敏,工业催化,蒙脱土负载[C_(14)mim]~+有机阳离子催化合成柠檬酸三丁酯.,2007,15(9),43-46
105.Borah M.,Ganguli J.N.,Dutta D.K.,Intersalation Reactions of Trisdiimine Metal Complexes with Montmorillonite Clay:A New Approach.,J.Colloid Interface Sci.,2001,233(2),171-179
106.雷立旭,忻新泉.,室温固相化学反应与固体结构.,化学通报,1997,(2),1-7
107.石恒真,陈建国,李敏,可膨胀层状硅酸盐粘土应用研究进展,化学通报,1998,(5),12
108.李海艳,李强.,有机染料-层状硅酸盐光活性纳米复合材料.,化学进展,2003,15(2),135-140
109.Fan X.,Xia C.,Advineula R.C.,Intercalation of polymerization initiators into montmorillonite nanopartiele platelets:free radical vs.anionic initiator clays.,Colloid Surface A,2003,219(1-3),75-86
110.Bongiovanni R.,Mazza D.,Ronchetti S.,Turcato E.A.,The influence of water on the intercalation of epoxy monomers in Na-montmorillonite.,J.Colloid Interface Sci.,2006, 296(2),515-519
111.徐如人,庞文琴.无机合成与制备化学,北京:高等教育出版社,2001,59
112.Kaupp G.,Schmeyers.,Boy.J.,Waste-free solid-state syntheses with quantitative yield.,Chemosphere,2001,43(1),55-61
113.唐新村,黄伯云,贺跃辉.,低热固相反应冷融熔机理和冷溶熔机理的证据.,无机化学学报,2005,21(1),12-14
114.Khaorapapong N.,Ogawa M.,Solid-state intercalation of 8-Hydroxyquinoline into Li(Ⅰ)-,Zn(Ⅱ)- and Mn(Ⅱ)-montmorillonites.,Appl.Clay Sci.,2007,35(1-2),31-38
1.Renaud F.,Piguet C.,Bernardinelli G.,Bunzli J.-C.G.,Hopfgartner G.Nine-Coordinate Lanthanide Podates with Predetermined Structural and Electronic Properties:Facial Organization of Unsymmetrical Tridentate Binding Units by a Protonated Covalent Tripod.,J.Am.Chem.Soc.,1999,121(40),9326-9342
2.莫尊里,高锦章,陈红,杨武,赵保卫.,新穴类大环配体.双环-N,N',N”-三-(1,4-苯基)-二-胺三乙酰胺和双环-N,N',N”-三-(1,2-苯基)-二-胺三乙酰胺的合成与表征.化学试剂,1999,21(3),131-132
3.Geary,W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122
4.Curtis N.F.,Curtis Y.M.,Some Nitrato-Amine Nickel(Ⅱ)Compounds with Monodentate and Bidentate Nitrate Ions.,Inorg.Chem.,1965,4(6),804-809
5.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
6.高锦章,杨武,康敬万,溶液中的镧系配合物光谱化学 pp:133-134
7.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.,Inorg.Chim.Acta.,1986,111:187-192.
8.Su C.-Y.Kang B.-S.,Liu H.-Q.,Wang Q.-G.,Chen Z.-N.,Lu Z.-L.,Tong Y.-X.,Mak T.C.W.,Luminescent Lanthanide Complexes with Encapsulating Polybenzimidazole Tripodal Ligands.,Inorg.Chem.,1999,38(7),1374-1375
9.Lowe M.P.,Rettig S.J.,Orvig C.,Highly Symmetric Group 13 Metal-Phosphinato Complexes:Multinuclear NMR(~(27)Al,~(31)P,~(71)Ga)Determination of Stability Constants at Low pH.J.Am.Chem.Soc.1996,118(43),10446-10456
10.(a)Setyawati I.A.,Liu S.,Rettig S.J.,Orvig C.,Homotrinuclear Lanthanide(Ⅲ)Arrays: Assembly of and Conversion from Mononuclear and Dinuclear Units.,Inorg.Chem.2000,39(3),496-507
(b)Yang X.-P.,Su C.-Y.,Kang B.-S.,Feng X.-L.,Xiao W.-L.,Liu H.-Q.,Studies on lanthainde complexes of the tripodal ligand N,N-bis(2-benzimidazolylmethyl)-N-(2-pyridylmethyl)amine Crystal structures and luminescent properties.,J.Chem.Soc.,Dalton Trans.2000,(19),3253-3260
11.Aoki C.,Ishida T.,Nogami T.,Molecular Metamagnet[Ni(41mNNH)_2(NO_3)_2](4ImNNH=4-Imidazolyl Nitronyl Nitroxide)and the Related Compounds Showing Supramolecular H-Bonding Interactions.,Inorg.Chem.,2003,42(23),7616-7625
12.Abrahams B.F.,Jackson P.A.,Robson R.,A robust(10,3)-a network containing chiral micropores in the Ag~I coordination polymer of a bridging ligand that provides three bidentate metal-binding sites.Angew Chem Int Ed Engl,1998,37(19):2656-2659
13.Kepert C.J.,Rosseinsky M.J.,A porous chiral framework of coordinated 1,3,5-benzenetricarboxylate:quadruple interpenetration of the(10,3)-a network.Chem Commun,1998,(1):31-32
14.Carlucci.L,Ciani.G.,Proserpio D M,Sironi A.A three-dimensional 'racemate',interpenetration of two enantiomeric networks of the SrSi_2 topological type in the polymeric complex[Ag_2(2,3-Me_2pyz)_3][SbF_6]_2.Chem Commun,1996,(11):1393-1394
15.Abrahams B.F.,Batten S.R.,Hamit.H.,Hoskins B.F.,Robson R.,A wellsian 'three-dimensional' racemete:eight interpenetrating enantiomorphic(10,3)-a nets,four right and four left-handed.Chem Commun,1996,(11):1313-1314
16.Shattock T.R.,Vishweshwar P.,Wang Z.,Zaworotko M.J.,18-Fold Interpenetration and concomitant polymorphism in the 2:3 Co-crystal of trimesic acid and 1,2-bis(4-pyridyl)ethane.Cryst Growth Des,2005,5(6):2046-2049
17.Sumby C.J.,Hardie M.J.,Disentangling disorder in the three-dimensional coordination network of {Ag_3[Tris(2-pyridylmethyl)cyclotrigualacylene]_2}(PF_6)_3.Cryst Growth Des,2005,5(4):1321-1324
18.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P280-281
19.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p244-251
20.Roesky H.W.,Andruh M.,The interplay of coordinative,hydrogen bonding and π-πstacking interactions in sustaining supramolecular solid-state architectures.:A study case of bis(4-pyridyl)- and bis(4-pyridyl-N-oxide)tectons.Coord.Chem.Rev.,2003,236(1-2),91-119.
21.Zafiropoulos T.F.,Plakatouras J.C.,Perlepes S.P.,Preparation and properties of complexes of lanthanide(Ⅲ)salts with n-(2-pyddyl)pyridine-2'-carboxamide Polyhedron,1991,10(20-21),2405-2415
22.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p316-321
23.Neogi S.,Savitha G.,Bharadwaj P.K.,Structure of Discrete(H_2O)_(12)Clusters Present in the Cavity of Polymeric Interlinked Metallocycles of Nd(Ⅲ)or Gd(Ⅲ)and a Podand Ligand.,Inorg.Chem.,2004,43(13),3771-3773
1.Tsukube H.,Hosokubo M.,Wada M.,Shinoda S.,Tamiaki H.,Specific Recognition of Chiral Amino Alcohols via Lanthanide Coordination Chemistry:Structural Optimization of Lanthanide Tris(diketonates)toward Effective Circular Dichroism/Fluorescence Probing.Inog.Chem.2001,40(4),740-745
2.Hanaoka K.,Kikuchi K.,Kobayashi S.,Nagano T.,Time-Resolved Long-Lived Luminescence Imaging Method Employing Luminescent Lanthanide Probes with a New Microscopy System.J.Am.Chem.Soc.,2007,129(44),13502-13509
3.Kessler M.A.,Probing the Dissociation State of Acid-Base Indicators by Time-Resolved Lanthanide Luminescence:A Convenient Transduction Scheme for Optical Chemical Sensors.Anal.Chem.1999,71(8),1540-1543
4.Liu Z.,Jiang L.,Liang Z.,Gao Y.,Photo-switchable molecular devices based on metal-ionic recognition.,Tetra.Lett.,2005,46(5),885-887
5.酰胺型开链配体与稀土配合物的研究,张剑毕业论文(硕士)2003,p62
6.Geary W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122.
7.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
8.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,p244-251
9.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.Inorg.Chim.Acta,1986,111,187-192.
10.Jeffrey G.A.,Maluszynska H.,Mitra.J.,Int.J.Biol.Macromol.,(1985),7,336-348
11.Steiner Th.,Cryst.Rev,(1996),6,1-57
12.Neogi S.,Savitha G.,Bharadwaj P.K.,Structure of Discrete(H_2O)_(12)Clusters Present in the Cavity of Polymeric Interlinked Metallocycles of Nd(Ⅲ)or Gd(Ⅲ)and a Podand Ligand.,Inorg.Chem.,2004,43(13),3771-3773.
1.Muller-Buschbaum K.,Gomez-Torres S.,Larsen P.,Wickleder C.,Crystal Engineering of Rare Earth Amides:~3_∞[Tb(Im)_3]@NH_3,a Homoleptic 3D Network Exhibiting Strong Luminescence.,Chem.Mater.,2007,19(4),655-659
2.Tzeng B.-C.,Huang Y.-C.,Chen B.-S.,Wu W.-M.,Lee S.-Y.,Lee G.-H.,Peng S.-M.,Crystal-Engineering Studies of Coordination Polymers and a Molecular-Looped Complex Containing Dipyridyl-Amide Ligands.,Inorg.Chem.,2007,46(1),186-195
3.Pallan P.S.,Von Matt P.,Wilds C.J.,Altmann K.-H.,Egli M.,RNA-Binding Affinities and Crystal Structure of Oligonucleotides Containing Five-Atom Amide-Based Backbone Structures.,Biochemistry,2006,45(26),8048-8057.
4.Videnova-Adrabinska V.,Coordination and supramolecular network entanglements of organodisulfonates.,Coord.Chem.Rev.,2007,251(15-16),1987-2016
5.Gunnlaugsson T.,Parker D.,Luminescent europium tetraazamacrocyclic complexes with wide range pH sensitivity.,Chem.Commun.,1998,511-512
6.Sarkar M.,Biradha K.,Crystal Engineering of Metal-Organic Frameworks Containing Amide Functionalities:Studies on Network Recognition,Transformations,and Exchange Dynamics of Guests and Anions Cryst.Growth Des.,2007,7(7),1318-1331
7.唐瑜,宋玉兰,蔡正洪,刘伟生,谭民裕.2,3-二(苄胺基甲酰基苯氧基-甲基)喹喔啉(L)稀土配合物的合成、表征及荧光性质研究.无机化学学报,2004,20(10),1233-1236
8.Dahrouch M.R.,Jara P.,Mendez L.,Portilla Y.,Abril D.,Alfonso,G.,Chavez I.,Manriquez J.M.,Riviere-Baudet M.,Riviere P.,Castel A.,Rouzaud J.,Gornitzka,H.,An Effective and Selective Route to 1,5-Dihydropolyalkylated s-Indacenes:Characterization of Their Mono- and Dianions by Silylation.Structure of trans-1,5-Bis(trimethylsilyl)-2,6-diethyl-4,8-dimethyl-s-indacene.,Organometallics,2001,20(26),5591-5597.
9.Li J.,Liu D.,Li Y.,Lee C.-S.,Kwong H.-L.,Lee S.,A High Tg Carbazole-Based Hole-Transporting Material for Organic Light-Emitting Devices.,Chem.Mater.,2005,17(5),1208-1212.
10.Geary W.J.,The use of conductivity measurements in organic solvents for the characterisation of coordination compounds.,Coord.Chem.Rev.,1971,7(1),81-122
11.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P251-255
12.Curtis N.F.,Curtis Y.M.,Some Nitrato-Amine Nickei(Ⅱ)Compounds with Monodentate and Bidentate Nitrate Ions.,Inorg.Chem.,1965,4(6),804-809
13.中本一雄,无机与配合物的红外和拉曼光谱,黄德如等译,北京:化学工业出版社,1991,P280-281
14.Mohan M.,Tandon J.P.,Grupta N.S.,Synthesis and characterization of some lanthanide(Ⅲ)chelates with O-hydroxyacetophenone oxime.Inorg.Chim.Acta.,1986,111,187-192
15.Fan J.,Sui B.,Okamura T-a.,Sun W.-Y.,Tang W.-X.,Ueyamab N.,Synthesis,structures and properties of two-dimensional honeycomb and stepwise networks from self-assembly of tripodal ligand 1,3,5-tris(imidazol-1-ylmethyl)-2,4,6-trimethylbenzene with metal salts.,J.Chem.Soc.,Dalton Trans.,2002,3868-3873
16.Aakeroy C.B.,Beatty A.M.,Helfrich B.A.,Two-fold interpenetration of 3-D nets assembled via three-co-ordinate silver(I)ions and amide-amide hydrogen bonds.,J.Chem.Soc.,Dalton Trans.,1998,1943-1945
17.Xu Z.,Kiang Y.-H.,Lee S.,Lobkovsky E.B.,Emmott N.,Hydrophilic-to-Hydrophobic Volume Ratios as Structural Determinant in Small-Length Scale Amphiphilic Crystalline Systems:Silver Salts of Phenylacetylene Nitriles with Pendant Oligo(ethylene Oxide)Chains.,J.Am.Chem.Soc.,2000,122(35),8376-8391
18.Wells A F.,Three-dimensional nets and polyhedra,Wiley-Interscience,New York,1977,p56-118
19.Ohrstrom L.,Larsson K.,What kinds of three-dimensional nets are possible with tris-chelated metal complexes as building blocks? J Chem Soc Dalton Trans,2004,(3),347-353
20.Shu M.H,Tu C.L,Xu W.D.,Jin H.B.,Sun J.,Reversible anion exchanges of porous metal-organic frameworks:syntheses and structures of silver complexes with novel rigid tripodal nitrogen ligands.Cryst Growth Des,2006,6(8),1890-1896
21.Abrahams B.F.,Jackson P.A.,Robson R.,A robust(10,3)-a network containing chiral micropores in the Ag~1 coordination polymer of a bridging ligand that provides three bidentate metal-binding sites.Angew Chem Int Ed Engl,1998,37(19),2656-2659
22.Kepert C.J.,Rosseinsky M.J.,A porous chiral framework of coordinated 1,3,5-benzenetricarboxylate:quadruple interpenetration of the(10,3)-a network.Chem Commun,1998,(1),31-32
23.Carlucci L.,Ciani G.,Proserpio D.M.,Sironi A.,A three-dimensional 'racemate', interpenetration of two enantiomeric networks of the SrSi_2 topological type in the polymeric complex[Ag_2(2,3-Me_2pyz)_3][SbF_6]_2.Chem Commun,1996,(11),1393-1394
24.Abrahams B.F.,Batten S.R.,Hamit H.,Hoskins B.F.,Robson R.,A wellsian 'three-dimensional' racemete:eight interpenetrating enantiomorphic(10,3)-a nets,four right and four left-handed.Chem Commun,1996,(11),1313-1314
25.Shattock T.R.,Vishweshwar P.,Wang Z.,Zaworotko M.J.,18-Fold Interpenetration and concomitant polymorphism in the 2:3 Co-crystal of trimesic acid and 1,2-bis(4-pyridyl)ethane.Cryst Growth Des,2005,5(6),2046-2049
26.Sumby C.J.,Hardie M.J.,Disentangling disorder in the three-dimensional coordination network of {Ag_3[Tris(2-pyridylmethyl)cyclotriguaiacylene]_2}(PF_6)_3.Cryst Growth Des,2005,5(4),1321-1324
1.Sabbatini N.,Guardigli M.,Lehn J.M.,Luminescent lanthanide complexes as photochemical supramolecular devices.,Coord.Chem.Rev.,1993,123(1-2),201-228
2.黄春辉.稀土配位化学[M].北京:科学技术出版社,1997,p363
3.Carnall W.T.,Handbook of the Physics and Chmistry of Rare Earths,Vol.3,Northholland,Amsterdam,1979,p171
4.Richardson F.S.,Terbium(Ⅲ)and europium(Ⅲ)ions as luminescent probes and stains for biomolecular systems.Chem.Rev.,1982,82(5),541-552
5.Hu X.,Cui S.,Yan L.,Yang R.D.,Synthesis,Characterization and Fluorescence of Rare earth Nitrate Complexes with Tdaza-crown Ether Derivative.,J.Rare Earths.2003,21(3),395-397.
6.苏锵,稀土化学.,第一版,郑州.河南技术出版社,1993,p310.
7.Martti L.,Hard T.,Veli-Matti M.,Cristina M.,Juan C.R.,Jouko K.,Correlation between the lowest triplet state energy level of the ligand and lanthanide(Ⅲ)luminescence quantum yield.,J.Lumin.,1997,75:149-169
8.Dexter D.L.,A Theory of Sensitized Luminescence in Solids.,J.Chem.Phys.,1953,21,836-850
9.Moore J.H.,Sato Y.,Staley S.W.,Energies and relative cross sections of singlet-triplet transitions in methyl-substituted 1,3-butadienes by ion-impact spectroscopy1965,69(3),1092-1095
10.Bassett,A.P.,Magennis,S.W.,Glover,P.B.,Lewis,D.J.,Spencer,N.,Parsons,S.,Williams,R.M.,De Cola,L.,Pikramenou,Z.,Highly Luminescent,Triple- and Quadruple-Stranded,Dinuclear Eu,Nd,and Sm(Ⅲ)Lanthanide Complexes Based on Bis-Diketonate Ligands.,J.Am.Chem.Soc.,2004;126(30);9413-9424.
11.Latva M.,Takalo H.,Mukkala V.-M.,Matachescu C.,Rodriguez-Ubis J.C.,Kankare J.,Correlation between the lowest triplet state energy level of the ligand and lanthanide(Ⅲ)luminescence quantum yield.,J.Lumin.1997,75(2),149-169
12.Blasse G.,Dirksen G.J.,Sabbatini N.,Perathoner S.,Lehn J.M.,Alpha B.,Luminescence processes in[Tb.cntnd.bpy.bpy.bpy]~(3+)cryptate:a low-temperature solid-state study.,J.Phys.Chem.,1988,92(9),2419-2422
13.Crosby G.A.,Whan R.E.,Freeman J.J.,SPECTROSCOPIC STUDIES OF RARE EARTH CHELATES.,J.Phys.Chem.;1962;66(12);2493-2499
14.闫冰,张洪杰,王淑彬,倪嘉瓒.Photophysical Properties of Rare Earth Complexes with 3,4 furandicarboxylic Acid and 1,10 phenanthroline中国稀土学报.1998,16(4),375-378
15.Sato S.,Wada.M.,Relations between intramolecular energy transfer efficiencies and triplet state energies in rare earth β-diketone chelates.,Bull.Chem.Soc.Jpn.,1970,43,1955-1959
1.Pinnavaia T.J.,Intercalated Clay Catalysts.,1983,220(4595),365-371
2.林鸿福,林峰,袁尉顺.制备纳米复合材料的天然矿物--蒙脱石.,化工新型材料,2001,29(4),20-27
3.沈家骢.超分子层状结构-组装与功能,北京:科学出版社,2003,p163
4.Borah M.,Ganguli J.N.,Dutta D.K.,Intersalation Reactions of Trisdiimine Metal Complexes with Montmodlionite Clay:A New Approach.,J.Colloid Interface Sci.,2001,233(2),171-179
5.Xu Q.H.,Fu L.S.,Li L.S.,Zhang H.J.,Xu R.R.,Preparation,charactedsation and photophysical properties of layered compounds zironium bis(Monohydrogenphosphate)intercalated rare earth complexes.,J.Mater.Chem.,2000,10,2532-2536
6.Ghosh P.K.,Bard A.J.,Photochemistry of tris(2,2'-bipyridyl)(ruthenium(Ⅱ)in colloidal clay suspensions.,J.Phys.Chem.,1984,88(23),5519-5526
7.Figueras F.,Pillared clays as catalysts.,Catal.Rev.Sci.Eng.,1988,30(3),457-459
8.Lakowicz J.R.,Principles of Fluorescence Spectroscopy,Plenum Press,New York,1983
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