参考文献:
[1]Hoskins B. F., Robson R. Infinite Polymeric Frameworks Consisting of Three Dimen-sionally Linked Rod-like Segments[J]. Journal of the American Chemical Society, 1989,111(15):5962-5964.
[2]Yoshizawa M., Ono K., Kumazawa K., et al.Metal-Metal d-d Interaction through the Discrete Stacking of Mononuclear M(II)Complexes(M = Pt, Pd, and Cu)within an Organic-Pillared Coordination Cage[J]. Journal of the American Chemical Society, 2005,127(37):10800-10801.
[3]Ohmori O., Fujita M. Heterogeneous catalysis of a coordination network:cyanosilylation of imines catalyzed by a Cd(II)-(4,4′-bipyridine)square grid complex[J]. Chemical Communications,2004, (14):1586-1587.
[4]Seo J. S., Whang D., Lee H., et al. A homochiral metal-organic porous material for enantioselective separation and catalysis[J]. Nature,2000, V404(6781):982-986.
[5]James S. L. Metal-organic frameworks[J]. Chemical Society Reviews,2003,32(5):276-288.
[6]Wang Y. T., Fan H. H., Wang H. Z., et al.A Solvothermally in situ Generated Mixed-ligand Approach for NLO-Active Metal-Organic Framework Materials[J]. Inorganic Chemistry,2005,44(12):4148-4150.
[7]Hou H., Wei Y., Song Y., et al.Metal Ions Play Different Roles in the Third-Order Nonlinear Optical Properties of d10 Metal-Organic Clusters[J]. Angewandte Chemie International Edition,2005,44(37):6067-6074.
[8]Becker P. Borate materials in nonlinear optics[J]. Advanced Materials,1998,10 (13):979-992.
[9]Wang H. S., Zhao B., Zhai B., et al. Syntheses, Structures, and Photoluminescence of One-Dimensional Lanthanide Coordination Polymers with 2,4,6-Pyridinetricarboxylic Acid [J]. Crystal Growth & Design,2007,7(9):1851-1857.
[10]Zhao B., Chen X. Y., Cheng P., et al.Coordination Polymers Containing 1D Channels as Selective Luminescent Probes[J]. Journal of the American Chemical Society, 2004,126:15394-15395.
[11]Wang X. L., Qin C., Wang E. B., et al.Metal Nuclearity Modulated Four-, Six-, and Eight-Connected Entangled Frameworks Based on Mono-, Bi-, and Trimetallic Cores as Nodes[J]. Chemistry-A European Journal,2006,12(10):2680-2691.
[12]Hu T. L., Zou R. Q., Li J. R., et al. d10 Metal Complexes Assembled from Isomeric Benzenedicarboxylates and 3-(2-pyridyl)pyrazole Showing 1D Chain Structures:Syn-theses, Structures and Luminescent Properties[J]. Dalton Transactions,2008,1302-1311.
[13]Liu C. M., Gao S., Zhang D. Q., et al.A Unique 3D Alternating Ferro-and Antifer-romagnetic Manganese Azide System with Threefold Interpenetrating(10,3)Nets [J]. Angewandte Chemie International Edition,2004,43(8):990-994.
[14]Muller R.N., Vander Elst L., Laurent S. Spin transition molecular materials:Intelli-gent contrast agents for magnetic resonance imaging[J]. Journal of the American Chemical Society,2003,125(27):8405-8407.
[15]Li K. H., Olsan D. H., Lee J. Y., et al. Multifunctional microporous MOFs exhibiting gas/hydrocarbon adsorption selectivity, separation capability and three-dimensional magnetic ordering[J]. Advanced Functional Materials,2008,18(15):2205-2214.
[16]Kitaura R., Kitagawa S., Kubota Y., et al. Formation of a one-dimensional array of oxygen in a microporous metal-organic solid[J]. Science,2002,298(5602):2358-2361.
[17]Heulings H. R., Huang X. Y., Li J., et al. Mn-substituted inorganic-organic hybrid materials based on ZnSe:Nanostructures that may lead to magnetic semiconductors with a strong quantum confinement effect[J]. Nano Letters,2001,1(10):521-525.
[18]Zhang J. P., Kitagawa S. Supramolecular isomerism, framework flexibility, unsaturated metal center, and porous property of Ag(I)/Cu(I)3,3′,5,5 ′-tetrametyl-4,4 ′-bi-pyrazolate[J]. Journal of the American Chemical Society,2008,130(3):907-917.
[19]Han S. S., Furukawa H., Yaghi O. M., et al. Covalent organic frameworks as excep-tional hydrogen storage materials[J]. Journal of the American Chemical Society, 2008,130(35):11580-11581.
[20]Rosi N. L., Eckert J., Eddaoudi M., et al. Hydrogen storage in microporous metal-organic frameworks[J]. Science,2003,300(5622):1127-1129.
[21]Min K. S., Suh M. P. Silver(I)-polynitrile network solids for anion exchange:Anion-induced transformation of supramolecular structure in the crystalline state[J]. Journal of the American Chemical Society,2000,122(29):6834-6840.
[22]Maji T. K., Matsuda R., Kitagawa S. A flexible interpenetrating coordination frame-work with a bimodal porous functionality[J]. Nature Materials,2007,6(2):142-148.
[23]Ouellett W., Hudson B. S., Zubieta J. Hydrothermal and Structural Chemistry of the Zinc(II)- and Cadmium(II)-1,2,4-Triazolate Systems[J]. Inorganic Chemistry, 2007,46(12):4887-4904.
[24]Park H., Britten J. F., Mueller U., et al. Synthesis, Structure Determination, and Hy-drogen Sorption Studies of New Metal-organic Frameworks Using Triazole and Naphtha-lenedicarboxylic Acid[J]. Chemistry of Materials,2007,19(6):1302-1308.
[25]Zhai Q. G., Lu C. Z., Chen S. M., et al. Design of Novel Three-Dimensional Coordi-nation Polymers Based on Triangular Trinuclear Copper 1,2,4-Triazolate Units[J]. Crystal Growth & Design,2006,6(6):1393-1398.
[26]Haasnoot J. G. Mononuclear, oligonuclear and polynuclear metal coordination com-pounds with 1,2,4-triazole derivatives as ligands[J]. Coordination Chemistry Re-view,2000,200-202:131-185.
[27]张建国,张同来,张志刚,等.唑类杂环化合物及其配合物的研究概述[J].含能材料,2001,9(2):90-93.
[28]Xue H., Gao Y., Brendan T., et al.New Energetic Salts Based on Nitrogen-Contai-ning Heterocycles[J]. Chemistry of Materials,2005,17(1):191-198.
[29]Wang R. H., Gao H. X., Ye C. F., et al.Strategies toward syntheses of triazolyl-or triazolium functionalized unsymmetrical energetic salts[J]. Chemistry of Materials, 2007,19(2):144-152.
[30]Zhai Q. G., Lu C. Z., Wu X. Y., et al. Coligand Modulated Six-, Eight-, and Ten-Connected Zn/Cd-1,2,4-Triazolate Frameworks Based on Mono-, Bi-, Tri-, Penta-, and Heptanuclear Cluster Units[J]. Crystal Growth & Design,2007,7 (11):2332-2342.
[31]Ding B., Yi L., Cheng P., et al. Synthesis and Characterization of a 3D Coordination Polymer Based on Trinuclear Triangular CuII as Secondary Building Units[J]. Inor-ganic Chemistry,2006,45(15):5799-5803.
[32]Bagihalli G. B., Badami P. S., Patil S. A. Synthesis, spectral characterization and in vitro biological studies of Co(II), Ni(II)and Cu(II)complexes with 1,2,4-triazole Schiff bases[J]. Journal of Enzyme Inhibition and Medicinal Chemistry,2009,24 (2):381-394.
[33]Brandt C. D., Kitchen J. A., Beckmann U., et al. Synthesis and structures of 3,5-disubstituted 1,2,4-triazole head units and incorporation of 3,5-dibenzoyl-1,2,4-triazolate into new [2+2]Schiff-base macrocyclic complexes[J]. Supramolecular Chemistry,2007,19(1-2):17-27.
[34]Zhang J. P., Chen X. M. Exceptional framework flexibility and sorption behavior of a multifunctional porous cuprous triazolate framework[J]. Journal of the American Chemical Society,2008,130(18):6010-6017.
[35]Zhang J. P., Chen X. M. Crystal engineering of binary metal imidazolate and triazolate frameworks[J]. Chemical Communications,2006, (16):1689-1699.
[36]Geldard J. F., Lions F. The Organic Chemistry of a New Weak Field Tridentate Chela-ting Agent.3,5-Di(2-pyridyl)-1,2,4-triazole[J]. The Journal of Organic Chemis-try,1965,30(1):318-319.
[37]Cheng L., Zhang W. X., Chen X. M., et al. In situ solvothermal generation of 1,2,4-triazolates and related compounds from organonitrile and hydrazine hydrate:A mechanism study[J]. Inorganic Chemistry,2007,46(4):1135-1143.
[38]Zhang J. P., Lin Y. Y., Chen X. M. Molecular chairs, zippers, zigzag and helical chains:chemical enumeration of supramolecular isomerism based on a predesigned metal-organic building-block[J]. Chemical Communications,2005, (10):1258-1260.
[39]Chen J. C., Zhou A. J., Tong M. L., et al. Synthesis, structure and magnetic property of a new mixed-valence copper(I/II)complex derived from 3,5-bis(pyridin-2-yl)-1, 2,4-triazole[J]. Journal of Molecular Structure,2006,794(1-3):225-229.
[40]Chen J. C., Hu S., Tong M. L., et al. Synthesis, crystal structures, and magnetic properties of three new iron complexes derived from 3,5-bis(pyridin-2-yl)-1,2,4-tria-zole[J]. Zeitschrift für anorganische und allgemeine Chemie,2006,632(3):475-481.
[41]Zhai Q. G., Wu X. Y., Chen S.M., et al. Construction of Cd/Zn(II)-1,2,4-triazo-late coordination complexes via changing substituents and anions[J]. Crystal Growth& Design,2006,6(9):2126-2135.
[42]Zhai Q. G., Hu M. C., Wang Y., et al. Synthesis and characterizations of a novel dia-type Ag-BPT coordination polymer with tetranuclear motifs as jointing points(BPT=5-bis(3-pyridyl)-1,2,4-triazole)[J]. Inorganic Chemistry Communications, 2009,12(4):286-289.
[43]Xie X. F., Chen S. P., Gao S. L., et al. Construction of metal-organic frameworks with transitional metals based on the 3,5-bis(4-pyridyl)-1H-1,2,4-triazole ligand [J]. Polyhedron,2009,28(4):679-688.
[44]Wang H. Y., Cheng J. Y., Dong Y. B., et al. Synthesis and Characterization of New Coordination Polymers with Tunable Luminescent Properties Generated from Bent 1, 2,4-Triazole-Bridged N, N'- Dioxides and Ln(III)Salts[J]. Inorganic Chemistry, 2010,49(5):2416-2426.
[45]Lin J. B., Zhang J. P., Zhang W. X., et al. Porous Manganese(II)3-(2-Pyridyl)-5-(4-Pyridyl)-1,2,4 -Triazolate Frameworks:Rational Self-Assembly, Supramolecular Isomerism, Solid-State Transformation, and Sorption Properties[J]. Inorganic Chemis-try,2009,48(14):6652-6660.
[46]Fu A. Y., Jiang Y. L., Wang Y. Y., et al. DMF/H2O Volume Ratio Controls the Syn-theses and Transformations of a Series of Cobalt Complexes Constructed Using a Rigid Angular Multitopic Ligand[J]. Inorganic Chemistry,2010,49(12):5495-5502.
[47]Meng Z. S., Yun L., Zhang W. X., et al. Reactivity of 4-amino-3,5-bis(pyridin-2-yl)-1,2,4-triazole, structures and magnetic properties of polynuclear and polymeric Mn(II), Cu(II)and Cd(II)complexes[J]. Dalton Transactions,2009, (46):10284-10295.
[48]Cheng L., Zhang W. X., Ye B. H., et al. Spin canting and topological ferrimagnetism in two manganese(II)coordination polymers generated by in situ solvothermal ligand reactions[J]. European Journal of Inorganic Chemistry,2007, (18):2668-2676.
[49]Garcia U., Castillo O., Cepeda J., et al. Structural and magnetic characterization of one-dimensional oxalato-bridged metal(II)complexes with 4-amino-3,5-bis(2-pyridyl)-1,2,4-triazole ligand:A supramolecular open-framework[J]. Inorganica Chimica Acta,2009,362(11):4212-4218.
[50]Du M., Zhang Z. H., You Y. P., et al. R-Isophthalate(R = -H, -NO2, and -COOH)as modular building blocks for mixed-ligand coordination polymers incorporated with a versatile connector 4-amino-3,5-bis(3-pyridyl)-1,2,4-triazole. CrystEngComm, 2008,10(3):306-321.
[51]Du M., Jiang X. J., Zhao X. J. Direction of unusual mixed-ligand metal-organic frameworks:a new type of 3-D polythreading involving 1-D and 2-D structural motifs and a 2-fold interpenetrating porous network[J]. Chemical Communications,2005, (44):5521-5523.
[52]Du M., Jiang X. J., Zhao X. J. Controllable Assembly of Metal-Directed Coordination Polymers under Diverse Conditions:A Case Study of the MII-H3tma/Bpt Mixed-Lig-and System[J]. Inorganic Chemistry,2006,45(10):3998-4006.
[53]Liu J. J., He X., Li M. X., et al. Syntheses, structures and thermal stabilities of four complexes with 4-amino-3,5-bis(3-pyridyl)-1,2,4-triazole ligand[J]. Journal of Molecular Structure,2008,891(1-3):50-57.
[54]Li M. X., Wang H., Liang S. W., et al. Solvothermal Synthesis and Diverse Coordinate Structures of a Series of Luminescent Copper(I)Thiocyanate Coordination Polymers Based on N-Heterocyclic Ligands[J]. Crystal Growth & Design,2009,9(11):4626-4633.
[55]Liu J. J., He X., Shao M., et al. Syntheses and topological networks of two azide com-plexes based on 4-amino-3,5-bis(3-pyridyl)-1,2,4-triazole ligands[J]. Inorganic Chemistry Communications,2009,12(10):972-974.
[56]Huang F. P., Tian J. L., Gu W., et al. Three 3D Cu(II)coordination polymers con-structed from 1,2,4,5-benzenetetracarboxylate acid and three positional isomeric lig-ands[J]. Inorganic Chemistry Communications,2010,13(1):90-94.
[57]Huang F. P., Tian J. L., Gu W., et al. Co(II)Coordination Polymers:Positional Iso-meric Effect, Structural and Magnetic Diversification[J]. Crystal Growth & Design, 2010,10(3):1145-1154.
[58]Huang F. P., Tian J. L., Chen G. J., et al. A case study of the ZnII-BDC/bpt mixed-ligand system:positional isomeric effect, structural diversification and luminescent properties[J]. CrystEngComm,12(4):1269-1279.
[59]Zhang L. P., Wan Y. H., Jin L. P. Hydrothermal synthesis and crystal structure of ne-odymium(III)coordination polymers with isophthalic acid and 1,10-phenanthroline [J]. Polyhedron,2003,22(7):981-987.
[60]Rosi N. L., Kim J., Eddaoudi M., et al. Rod Packings and Metal-organic Frameworks Constructed from Rod-Shaped Secondary Building Units[J]. Journal of the American Chemical Society,2005,127(5):1504-1518.
[61]Rosi N. L., Eddaoudi M., Kim J., et al. Advances in the chemistry of metal-organic frameworks[J]. CrystEngComm,2002,4(68):401-404.
[62]Lin J. D., Lin M. Z., Tian C. B., et al. Syntheses, topological structures and physical properties of two 2D lanthanide-organic frameworks constructed from 5-nitroisophthalic acid[J]. Journal of Molecular Structure,2009,938(1-3):111-116.
[63]Abourahma H., Moulton B., Kravtsov V., et al. Supramolecular Isomerism in Coordina-tion Compounds:Nanoscale Molecular Hexagons and Chains[J]. Journal of the Amer-ican Chemical Society,2002,124(34):9990-9991.
[64]Ye J., Zhang J., Ning G., et al. Lanthanide Coordination Polymers Constructed from Dinu-clear Building Blocks:Novel Structure Evolution from One-Dimensional Chains to Three-Dimensional Architectures[J]. Crystal Growth&Design,2008,8(8):3098-3106.
[65]Burrows A. D., Frost C. G., Mahon M. F., et al. Subtle structural variation in copper metal-organic frameworks:syntheses, structures, magnetic properties and catalytic behaviour[J]. Dalton Transactions,2008, (47):6788-6795.
[66]Wang D. E., Deng K. J., Lv K. L., et al. Structures, photoluminescence and photocat-alytic properties of three new metal-organic frameworks based on non-rigid long bridges. CrystEngComm,2009,11(7):1442-1450.
[67]Wu C. D., Lu C. Z., Yang W. B., et al. Hydrothermal Synthesis, Structures, and Magnetic Properties of Three Novel 5-Aminoisophthalic Acid Ligand Bridged Transi-tion Metal Cation Polymers[J]. Inorganic Chemistry,2002,41(12):3302-3307.
[68]Zeng M. H., Hu S., Chen Q., et al. Apical Ligand Substitution, Shape Recognition,Vapor-Adsorption Phenomenon, and Microcalorimetry for a Pillared Bilayer Porous Framework That Shrinks or Expands in Crystal-to-Crystal Manners upon Change in the Cobalt(II)Coordination Environment[J]. Inorganic Chemistry,2009,48(15):7070-7079.
[69]Furukawa H., Kim J., Yaghi O. M., et al. Control of Vertex Geometry, Structure Di-mensionality, Functionality, and Pore Metrics in the Reticular Synthesis of Crystalline Metal-organic Frameworks and Polyhedra[J]. Journal of the American Chemical So-ciety,2008,130(35):11650-11661.
[70]Hu Y., Zhang W., Zhang X., et al. Two corrugated 2D bilayer(63)(658)topological coordination polymers:Synthesis, structure, and water-induced reversible transforma-tion[J]. Inorganic Chemistry Communications,2009,12(2):166-168.
[71]Deng Q. J., Wu M. C., Zeng M. H., et al. Two supramolecular isomers of dimeric co-balt(II)5-aminoisophthalate:2D(4,63)vs 3D Rutile nets[J]. Journal of Molecular Structure,2008,876(1-3):162-169.
[72]Zhang K. L., Qiao N., Gao H. Y., et al. Self assembly of two novel three-dimensional supramolecular networks with blue photoluminescence. Polyhedron,2007,26(12):2461-2469.
[73]Si S., Li C., Wang R., et al. Ternary oxalate-bridged lanthanide complexes from hy-drothermal reactions[J]. Journal of Molecular Structure,2004,703(1-3):11-17.
[74]Du M., Jiang X. J., Zhao X. J. Molecular Tectonics of Mixed-Ligand Metal-Organic Frameworks:Positional Isomeric Effect, Metal-Directed Assembly, and Structural Di-versification[J]. Inorganic Chemistry,2007,46(10):3984-3995.