Координационные полимеры с магнитными 3d-и 4f-металлоцентрами: способы химической сборки, строение, сорбционные и магнитные свойства
Диссертация
Несмотря на то, что магнитоактивных соединений известно довольно много, включая различного рода координационные полимеры с парамагнитными ионами dи /-элементов, а также полиядерные кластеры разного состава и строения, в том числе ионные системы, или супрамолекулярные структуры, образующиеся в кристаллах за счет невалентных взаимодействий, лишь очень немногие из них обладают пустотами… Читать ещё >
Список литературы
- Maspoch D., Ruiz-Molina D., Veciana J. Magnetic nanoporous coordination polymers // J. Mater. Chem. 2004. V. 14. P. 2713−2723.
- Coulon C., Miyasaka H., Clerac R. Single-Chain Magnets: Theoretical Approach and Experimental Systems // Structure and Bonding. 2006. V. 122. P. 163−206.
- Aromi G., Brechin E. K. Synthesis of 3d Metallic Single-Molecule Magnets // Structure and Bonding. 2006. V. 122. P. 1−68.
- Cornia A., Costantino A. F., Zobbi L., Caneschi A., Gatteschi D., Mannini M., Sessoli R. Preparation of Novel Materials Using SMMs // Structure and Bonding. 2006. V. 122. P. 133−161.
- Christou G. Single-molecule magnets: a molecular approach to nanoscale magnetic materials // Polyhedron. 2005. V. 24. P. 2065−2075.
- Karotsis G., Teat S. J., Wernsdor W., Piligkos S., Dalgarno S. J., Brechin E. K. Calix4. arene Based Single-Molecule Magnets // Angew. Chem. Int. Ed. 2009. V. 48. P. 8285−8288.
- Qiu S., Zhu G. Molecular engineering for synthesizing novel structures of metal-organic frameworks with multifunctional properties // Coord. Chem. Rev. 2009. V. 253. P. 2891−2911.
- Zhang J.-P., Zhang Y.-B., Lin J.-B., Chen X.-M. Metal Azolate Frameworks: From Crystal Engineering to Functional Materials // Chem. Rev. 2012. V. 112. P. 1001−1033.
- Janiak C., Vieth J. K. MOFs, MILs and more: concepts, properties and applications for porous coordination networks (PCNs) // New J. Chem. 2010. V. 34. P. 2366−2388.
- Custelcean R., Moyer B. A. Anion Separation with Metal-Organic Frameworks // Eur. J. Inorg. Chem. 2007. P. 1321−1340.
- Kitagawa S., Kitaura R., Noro S. Functional Porous Coordination Polymers // Angew. Chem. Int. Ed. 2004. V. 43. P. 2334−2375.
- Moulton B., Zaworotko M. J. Coordination polymers: toward functional transition metal sustained materials and supermolecules // Curr. Opinion Solid
- State Mater. Sci. 2002. V. 6. P. 117−123.
- James S. L. Metal-organic frameworks // Chem. Soc. Rev. 2003. V. 32. P. 276 288.
- Decurtins S., Pellaux R., Antorrena G., Palacio F. Multifunctional coordination compounds: design and properties // Coord. Chem. Rev. 1999. V. 190−192. P. 841−854.
- Llabres i Xamena F. X., Corma A., Garcia H. Applications for Metal-Organic Frameworks (MOFs) as Quantum Dot Semiconductors // J. Phys. Chem. C. 2007. V. Ill, No. 1. P. 80−85.
- Allendorf M. D., Bauer C. A., Bhakta R. K., Houk R. J. T. Luminescent metal-organic frameworks // Chem. Soc. Rev. 2009. V. 38. P. 1330−1352.
- Kreno L. E., Leong K., Farha O. K., Allendorf M., Van Duyne R. P., Hupp J. T. Metal-Organic Framework Materials as Chemical Sensors // Chem. Rev. 2012. V. 112. P. 1105−1125.
- Zou R., Abdel-Fattah A. I., Xu H., Zhao Y., Hickmott D. D. Storage and separation applications of nanoporous metal-organic frameworks // Cryst. Eng. Commun. 2010. V. 12. P. 1337−1353.
- Wu H., Gong Q., Olson D. H., Li J. Commensurate Adsorption of Hydrocarbons and Alcohols in Microporous Metal Organic Frameworks // Chem. Rev. 2012. V. 112. P. 836−868.
- Li J.-R., Kuppler R. J., Zhou H.-C. Selective gas adsorption and separation in metal-organic frameworks // Chem. Soc. Rev. 2009. V. 38. P. 1477−1504.
- Rosseinsky M. J. Recent developments in metal-organic framework chemistry: design, discovery, permanent porosity and flexibility // Microporous and Mesoporous Materials. 2004. V. 73. P. 15−30
- Lin X., Jia J., Zhao X., Thomas K. M., Blake A. J., Walker G. S., Champness N. R., Hubberstey P., Schroder M. High H2 Adsorption by Coordination-Framework Materials // Angew. Chem. Int. Ed. 2006. V. 45. P. 7358 -7364.
- Eddaoudi M., Kim J., Rosi N., Vodak D., Wachter J., O’Keeffe M., Yaghi O. M. Systematic Design of Pore Size and Functionality in Isoreticular MOFs and Their Application in Methane Storage // Science. 2002. V. 295. P. 469−472.
- Natarajan S., Mandal S. Open-Framework Structures of Transition-Metal
- Compounds // Angew. Chem. Int. Ed. 2008. V. 47. P. 4798 4828.
- Verdaguer M. Rational synthesis of molecular magnetic materials: a tribute to Olivier Kahn // Polyhedron. 2001. V. 20. P. 1115−1128.
- Yang Z., Xia Y., Mokaya R. Enhanced Hydrogen Storage Capacity of High Surface Area Zeolite-like Carbon Materials // J. Am. Chem. Soc. 2007. V. 129. P.1673−1679.
- Ferey G., Mellot-Draznieks C., Serre C., Millange F. Crystallized Frameworks with Giant Pores: Are There Limits to the Possible? // Acc. Chem. Res. 2005. V. 38. P. 217−225.
- Sieves K. J. Balkus, J. R. Synthesis of Large Pore Zeolites and Molecular // Prog. Inorg. Chem. 2001. V. 50. P. 217−268.
- Zhao X. S., Su F., Yan Q., Guo W., Bao X. Y., Lv L., Zhou Z. Templating methods for preparation of porous structures // J. Mater. Chem. 2006. V. 16. P. 637−648.
- Jiang J., Yu J., Corma A. Extra-Large-Pore Zeolites: Bridging the Gap between Micro and Mesoporous Structures // Angew. Chem. Int. Ed. 2010. V. 49. P. 3120−3145.
- Jiao K., Zhang B., Yue B., Ren Y., Liu S., Yan S., Dickinson C., Zhou W., He H. Growth of porous single-crystal Cr203 in a 3-D mesopore system // Chem. Commun. 2005. P. 5618−5620.
- Coronas J. Present and future synthesis challenges for zeolites // Chem. Eng. J. 2010. V. 156. P. 236−242.
- Feng P., Bu X., Tolbert S. H., Stucky G. D. Syntheses and Characterizations of Chiral Tetrahedral Cobalt Phosphates with Zeolite ABW and Related Frameworks // J. Am. Chem. Soc. 1997. V. 119. P. 2497−2504.
- Banerjee R., Phan A., Wang B., Knobler C., Furukawa H., O’Keeffe M., Yaghi O. M. High-Throughput Synthesis of Zeolitic Imidazolate Frameworks and Application to C02 Capture // Science. 2008. V. 319. P. 939−943.
- Hayashi H., Cote A. P., Furukawa H., O’Keeffe M., Yaghi O. M. Zeolite A imidazolate frameworks //Nature Materials. 2007. V. 6. P. 501−506.
- Edler K. J., Reynolds P. A., Branton P. J., Trouw F. R., White J. W. Structure and dynamics of hydrogen sorption in mesoporous MCM-41 // J. Chem. Soc.,
- Faraday Trans. 1997. V. 93. P. 1667−16 741.
- Vasilieva L. L., Kanonchika L. E., Kulakova A. G., Mishkinisa D. A., Safonova A. M., Luneva N. K. Newsorbent materials for the hydrogen storage and transportation // Int. J. Hydrogen Energy. 2007. V. 32. P. 5015−5025.
- Sumida K., Hill M. R., Horike S., Dailly A., Long J. R. Synthesis and Hydrogen Storage Properties of Bel2(OH)12(l, 3,5-benzenetribenzoate)4 // J. Am. Chem. Soc. 2009. V. 131. P. 15 120−15 121.
- Furukawa H., Miller M. A., Yaghi O. M. Independent verification of the saturation hydrogen uptake in MOF-177 and establishment of a benchmark for hydrogen adsorption in metal-organic frameworks // J. Mater. Chem. 2007. V. 17. P.3197−3204.
- Furukawa H., Ko N., Go Y. B., Aratani N., Choi S. B., Choi E., Yazaydin A. O., Snurr R. Q., O’Keeffe M., Kim J., Yaghi O. M. Ultrahigh Porosity in Metal-Organic Frameworks // Science. 2010. V. 329. P. 424−428.
- Ferey G., Serre C. Large breathing e. ects in three-dimensional porous hybrid matter: facts, analyses, rules and consequences // Chem. Soc. Rev. 2009. V. 38. P. 1380−1399.
- Rowsell J. L. C., Yaghi O. M. Metal-organic frameworks: a new class of porous materials // Microporous and Mesoporous Materials. 2004. V. 73. P. 3−14.
- Fischer R. A., Woll C. Functionalized Coordination Space in Metal-Organic Frameworks // Angew. Chem. Int. Ed. 2008. V. 47. P.8164−8168.
- Batten S.R., Neville S.M., Turner D.R., Coordination Polymers: Design, Analysis and Application // ISBN: 978−1-84 755−886−2, 2009.
- Champness N.R. Coordination frameworks—where next? // Dalton Trans. 2006. P. 877−880.
- Maspoch D., Ruiz-Molina D., Veciana J. Old materials with new tricks: multifunctional open-framework materials // Chem. Soc. Rev. 2007. V. 36. P. 770−818.
- Hoskins B. F., Robson R. Infinite polymeric frameworks consisting of three dimensionally linked rod-like segments // J. Am. Chem. Soc. 1989. V. 111. P. 5962 5964.
- Hoskins B. F., Robson R. Design and Construction of a New Class of
- Robson R. Design and its limitations in the construction of bi- and poly-nuclear coordination complexes and coordination polymers (aka MOFs): a personal view//Dalton Trans. 2008. P.5113−5131.
- Frontiers in Crystal Engineering. Eds: E. R. T. Tiekink, J. J. Vittal. John Wiley & Sons, Ltd. 2006.
- Uemura K. Matsudab R., Kitagawa S. Flexible microporous coordination polymers // J. of Solid State Chem. 2005. V. 178. P. 2420−2429.
- Kitagawa S., Uemura K. Dynamic porous properties of coordination polymers inspired by hydrogen bonds // Chem. Soc. Rev. 2005. V. 34. P. 109−119.
- Li H., Eddaoudi M., O’Keeffe M., Yaghi O.M. Design and synthesis of an exceptionally stable and highly porous metal-organic framework // Nature. 1999. V. 402. P. 276−279.
- Noro S.-I., Kitagawa S., Kondo M., Seki K. A New, Methane Adsorbent, Porous Coordination Polymer {CuSiF6(4,4'-bipyridine)2}n. // Angew. Chem. Int. Ed. 2000. V. 39. P. 2081−2084.
- Takamizawa S. Making Crystals by Design: Nanoporosity, Gas Storage, Gas Sensing. Wiley-VCH, Weinheim, 2007.
- Cui Y., Ngo H. L., Lin W. A homochiral triple helix constructed from an axially chiral bipyridine // Chem. Commun. 2003. P. 1388−1389.
- Moon H. R., Kim J. H., Suh M. P. Redox-Active Porous Metal-Organic Framework Producing Silver Nanoparticles from Agl Ions at Room Temperature //Angew. Chem., Int. Ed. 2005. V.44. P. 1261−1265.
- Colombo V., Galli S., Choi H. J., Han G. D., Maspero A., Palmisano G., Masciocchic N., Long J. R. High thermal and chemical stability in pyrazolate-bridged metal-organic frameworks with exposed metal sites // Chem. Commun. 2011.P. 1311−1319.
- P. Ball, Bright Earth: Art and the Invention of Color, Farrar, Straus and Giroux, New York, 2001.
- Takamizawa S., Nakata E., Miyake R. Structural susceptibility of gas inclusion crystal to external gas pressure and temperature: force guide role of channel // Dalton Trans. 2009, P. 1752−1760.
- Cotton F.A., Felthouse T.R. Pyridine and Pyrazine Adducts of Tetrakis (acetato)dichromium // Inorg.Chem. 1980, V. 19, P. 328−331.
- Takamizawa S., Nakata E., Saito T. Structural determination of copper (II) benzoate-pyrazine containing carbon dioxide molecules // Inorg. Chem. Commun. 2004, V. 7, P. 1−3.
- Smith G., Kennard C. H. L., Byriel K. A. The preparation and crystal structure determination of a polymeric adduct of copper (II) acetate with 2-aminopyrimidine//Polyhedron. 1991. V. 10. P. 873−876.
- Domasevitch K. V., Gural’skiy I. A., Solntsev P. V., Rusanov E. B., Krautscheid H., Howard J. A. K., Chernega A. N. 4,4'-Bipyridazine: a new twist for thesynthesis of coordination polymers // Dalton Trans. 2007. P. 3140−3148.
- Hu H.-L., Suen M.-C., Yeh C.-W., Chen J.-D. Synthesis and structures of two new copper (II) coordination polymers with pyridyl ligands // Polyhedron, 2005. V. 24. P.1497−1502.
- Batten S.R., Hoskins B.F., Moubaraki B., Murray K.S., Robson R. An alternative to interpenetration whereby nets with large windows may achieve satisfactory space filling// Chem. Commun. 2000. P.1095−1096.
- Papaefstathiou G. S., MacGillivray L. R. An Inverted Metal-Organic Framework with Compartmentalized Cavities Constructed by Using an Organic Bridging Unit Derived from the Solid State // Angew. Chem., Int. Ed. 2002. V. 41. P. 2070−2073.
- Ohmura T., Usuki A., Fukumori K., Ohta T., Ito M., Tatsumi K. New Porphyrin-Based Metal-Organic Framework with High Porosity: 2-D Infinite 22.2-A Square-Grid Coordination Network // Inorg. Chem. 2006. V. 45. P. 7988−7990.
- Liu H.-B., Yu S.-Y., Huang H., Zhang Z.-X. Enclathrating Benzene in a Neutral Dicopper (II) Coordination Framework // Australian J. Chem. 2003. V. 56. P. 671 -674.
- Ryan P. E., Lescop C., Laliberte D., Hamilton T., Maris T., Wuest J. D. Engineering New Metal-Organic Frameworks Built from Flexible Tetrapyridines Coordinated to Cu (II) and Cu (I) // Inorg. Chem. 2009. V. 48. P. 2793−2807.
- Zartilas S., Moushi E. E., Nastopoulos V., Boudalis A. K., Tasiopoulos A. J. Two new coordination polymers containing the triangular Mn30(02CR)6.0/+ units//Inorg. Chim. Acta, 2008. V. 361. P. 4100−4106.
- Albores P., Rentschler E. Structural and Magnetic Characterization of a ?0.-1,5-Dicyanamide-Bridged Iron Basic Carboxylate Fe30(02C (CH3)3)6. ID Chain //Inorg. Chem. 2008. V. 47. P. 7960−7962.
- Catenaccio A., Daruich Y., Magallanes С. Temperature dependence of the permittivity of water // Chem. Phys. Lett. 2003. V. 367. P. 669−671.
- Forster P. M., Burbank A. R., Livage C., Ferey G., Cheetham A. K. The role of temperature in the synthesis of hybrid inorganic-organic materials: the example of cobalt succinates // Chem. Commun. 2004. No. 4. P. 368−369.
- Walton K. S., Snurr R. Q. Applicability of the BET Method for Determining Surface Areas of Microporous Metal-Organic Frameworks // J. Am. Chem. Soc. 2007. V. 129. P. 8552−8556.
- Terzyk A. P., Gauden P. A., Kowalczyk P. What kind of pore size distribution is assumed in the Dubinin-Astakhov adsorption isotherm equation? // Carbon. 2002. V. 40. P. 2879−2886.
- С. Грег, К. Синг. Адсорбция, удельная поверхность, пористость. Москва: «Мир», 1970, 407 с.
- Wong-Foy A. G., Matzger A. J., Yaghi О. M. Exceptional H2 Saturation Uptake in Microporous Metal-Organic Frameworks // J. Am. Chem. Soc. 2006. V. 128. P. 3494−3495.
- Murray L. J., Dinca M., Long J. R. Hydrogen storage in metal-organic frameworks // Chem. Soc. Rev. 2009. V. 38. P. 1294−1314.
- Suh M. P., Park H. J., Prasad Т. K., Lim D.-W. Hydrogen Storage in Metal-Organic Frameworks // Chem. Rev. 2012. V. 112. P. 782−835.
- Rowsell J. L. C., Millward A. R., Park K. S., Yaghi O. M. Hydrogen Sorption in Functionalized Metal-Organic Frameworks // J. Am. Chem. Soc. 2004. V. 126. P. 5666−5667.
- Kaye S. S., Long J. R. Hydrogen Storage in the Dehydrated Prussian Blue Analogues M3Co (CN)6.2 (M = Mn, Fe, Co, Ni, Cu, Zn) // J. Am. Chem. Soc.2005. V. 127. P. 6506−6507.
- Chen B., Ockwig N. W., Millward A. R., Contreras D. S., Yaghi O. M. Framework with Open Metal Sites // Angew. Chem. Int. Ed. 2005. V. 44. P. 4745.4749.
- Lee J. Y., Pan L., Kelly S. P., Jagiello J., Emge T. J., Li J. Achieving High Density of Adsorbed Hydrogen in Microporous Metal Organic Frameworks // Adv. Mater. 2005. V. 17. P. 2703−2706.
- Chae H. K., Siberio-Perez D. Y., Kim J., Go Y.-B., Eddaoudi M., Matzger A. J., O’Keeffe M., Yaghi O. M. A route to high surface area, porosity and inclusion of large molecules in crystals // Nature. 2004. V. 427. P. 523−527.
- Latroche M., Surble S., Serre C., Mellot-Draznieks C., Llewellyn P. L., Lee JH., Chang J.-S., Jhung S. H., Ferey G. Hydrogen Storage in the Giant-Pore Metal-Organic Frameworks MIL-100 and MIL-101 // Angew. Chem. Int. Ed.2006. V. 45. P. 8227−8231.
- Ferey G., Latroche M., Serre C., Millange F., Loiseau T., Percheron-Guegan A. Hydrogen adsorption in the nanoporous metal-benzenedicarboxylate M (0H)(02C-C6H4-C02) (M = A13+, Cr3+), MIL-53 // Chem. Commun. 2003. P. 2976−2977.
- Surble S., Millange F., Serre C., Duren T., Latroche M., Bourrelly S., Llewellyn P. L., Ferey G. Synthesis of MIL-102, a Chromium Carboxylate Metal-Organic Framework, with Gas Sorption Analysis // J. Am. Chem. Soc. 2006. V. 128. P. 14 889−14 896.
- Park K. S., Ni Z., Cote A. P., Choi J. Y., Huang R., Uribe-Romo F. J., Chae H. K., O’Keeffe M., Yaghi O. M. Exceptional chemical and thermal stability of zeolitic imidazolate frameworks // Proc. Natl. Acad. Sei. USA. 2006. V.103. P. 10 186−10 191.
- Chen B., Ma S., Zapata F., Lobkovsky E. B., Yang J. Hydrogen Adsorption inan Interpenetrated Dynamic Metal-Organic Framework // Inorg. Chem. 2006. V. 45. P. 5718−5720.
- Dietzel P. D. C., Panella B., Hirscher M., Blom R., Fjellvag H. Hydrogen adsorption in a nickel based coordination polymer with open metal sites in the cylindrical cavities of the desolvated framework // Chem. Commun. 2006. P. 959−961.
- Carrott M. L. R., Candeias A. J. E, Carrott P. J. M, Ravikovitch P. I., Neimark
- A. V., Sequeira A. D. Adsorption of nitrogen, neopentane, n-hexane, benzene and methanol for the evaluation of pore sizes in silica grades of MCM-41 // Microporous and Mesoporous Materials. 2001. V. 47. P. 323−337.
- Duren T., Millange F., Ferey G., Walton K. S., Snurr R. Q. Calculating geometric surface areas as a characterization tool for metal-organic frameworks //J. Phys. Chem. C. 2007. V. 111. P. 15 350−15 356.
- Frost H., Duren T., Snurr R. Q. Effects of surface area, free volume, and heat of adsorption on hydrogen uptake in metal-organic frameworks // J. Phys. Chem.
- B. 2006. V. 110. P. 9565−9570.
- Lee J. Y., Li J., Jagiello J. Gas sorption properties of microporous metal organic frameworks // J. Solid State Chem. 2005. V. 178. P. 2527−2532.
- Dunca M., Long J. R. Strong H2 Binding and Selective Gas Adsorption within the Microporous Coordination Solid Mg3(02C-C10H6-C02)3 // J. Am. Chem. Soc. 2005. V. 127. P. 9376−9377.
- Nadeem M. A., Thornton A. W., Hill M. R., Stride J. A. A flexible copper based microporous metal-organic framework displaying selective adsorption of hydrogen over nitrogen // Dalton Trans. 2011. V. 40. P. 3398−3401.
- Ma S. Q., Wang X. S., Yuan D. Q., Zhou H.-C. A Coordinatively Linked Yb Metal-Organic Framework Demonstrates High Thermal Stability and Uncommon Gas-Adsorption Selectivity // Angew. Chem., Int. Ed. 2008. V. 47. P.413 0—4133.
- Dybtsev D. N., Chun H., Yoon S. H., Kim D., Kim K. Microporous Manganese Formate: A Simple Metal-Organic Porous Material with High Framework Stability and Highly Selective Gas Sorption Properties // J. Am. Chem. Soc. 2004. V. 126. P. 32−33.
- Li C.-J., Lin Z.-j., Peng M.-X., Leng J.-D., Yang M.-M., Tong M.-L.Novel three-dimensional 3d-4f microporous magnets exhibiting selective gas adsorption behavior// Chem. Commun. 2008. P. 6348−6350.
- Xue M., Zhang Z., Xiang S., Jin Z., Liang C., Zhu G.-S., Qiu S.-L., Chen B. Selective gas adsorption within a five-connected porous metal-organic framework // J. Mater. Chem. 2010. V. 20. P. 3984−3988.
- Bae Y.-S., Farha O. K., Hupp J. T., Snurr R. Q. Enhancement of C02/N2 selectivity in a metal-organic framework by cavity modification // J. Mater. Chem., 2009. V. 19. P. 2131−2134.
- Deng H., Doonan C. J., Furukawa H., Ferreira R. B., Towne J., Knobler C. B., Wang B., Yaghi O. M. Multiple Functional Groups of Varying Ratios in Metal-Organic Frameworks // Science. 2010. V. 327. P. 846 -850.
- Mallick A., Saha S., Pachfule P., Roy S., Banerjee R. Selective C02 and H2 adsorption in a chiral magnesium-based metal organic framework (Mg-MOF) with open metal sites // J. Mater. Chem., 2010. V. 20. P. 9073−9080.
- Chen B., Ma S., Zapata F., Fronczek F. R., Lobkovsky E. B., Zhou H.-C. Rationally Designed Micropores within a Metal-Organic Framework for Selective Sorption of Gas Molecules // Inorg. Chem. 2007. V. 46. P. 12 331 236.
- Iremonger S. S., Southon P. D., Kepert C. J. A nanoporous chiral metal-organic framework material that exhibits reversible guest adsorption // Dalton Trans. 2008. P. 6103−6105.
- Fang Q.-R., Zhu G.-S., Jin Z., Xue M., Wei X., Wang D.-J., Qiu S.-L. A Novel Metal-Organic Framework with the Diamondoid Topology Constructedfrom Pentanuclear Zinc-Carboxylate Clusters // Crystal Growth & Design. 2007. V.7. P. 1035−1037.
- Fang Q., Zhu G., Xue M., Sun J., Sun F., Qiu S. Structure, Luminescence, and Adsorption Properties of Two Chiral Microporous Metal-Organic Frameworks // Inorg. Chem. 2006. V. 45. P. 3582−3587.
- Nalaparaju A., Zhao X. S., Jiang J. W. Molecular Understanding for the Adsorption of Water and Alcohols in Hydrophilic and Hydrophobic Zeolitic Metal-Organic Frameworks // J. Phys. Chem. C. 2010. V. 114. P. 1 154 211 550.
- Volkringer C., Loiseau T., Guillou N., Ferey G., Elkai’m E., Vimont A. XRD and IR structural investigations of a particular breathing effect in the MOF-type gallium terephthalate MIL-53(Ga) // Dalton Trans. 2009. P. 2241−2249.
- Sumida K., Foo M. L., Horike S., Long J. R. Synthesis and Structural Flexibility of a Series of Copper (II) Azolate-Based Metal-Organic Frameworks // Eur. J. Inorg. Chem. 2010. P. 3739−3744.
- Millange F., Serre C., Guillou N., Ferey G., Walton R. I. Structural Effects of Solvents on the Breathing of Metal-Organic Frameworks: An In Situ Diffraction Study // Angew. Chem. Int. Ed. 2008. V. 47. P. 4100 -^105.
- Tabares L. C., Navarro J. A. R., Salas J. M. Cooperative Guest Inclusion by a Zeolite Analogue Coordination Polymer. Sorption Behavior with Gases and Amine and Group 1 Metal Salts // J. Am. Chem. Soc. 2001. V. 123. P. 383−387.
- Aijaz A., Lama P., Bharadwaj P. K. A Dynamically Entangled Coordination Polymer: Synthesis, Structure, Luminescence, Single-Crystal-to-Single-Crystal Reversible Guest Inclusion and Structural Transformation // Eur. J. Inorg. Chem. 2010. P. 3829−3834.
- Li N., Jiang F., Chen L., Li X., Chen Q., Hong M. From discrete octahedral nanocages to ID coordination polymer: Coordination-driven a single-crystal-to-single-crystal transformation via anion exchange // Chem. Commun. 2011. V. 47. P. 2327−2329.
- Biradha K., Hongo Y., Fujita M. Crystal-to-Crystal Sliding of 2D Coordination Layers Triggered by Guest Exchange // Angew. Chem. Int. Ed. 2002. V. 41. P. 3395−3398.
- Biradha K., Fujita M. A Springlike 3D-Coordination Network That Shrinks or Swells in a Crystal-to-Crystal Manner upon Guest Removal or Readsorption // Angew. Chem. Int. Ed. 2002. V. 41. P. 3392−3395.
- Chun H., Seo J. Discrimination of Small Gas Molecules through Adsorption: Reverse Selectivity for Hydrogen in a Flexible Metal-Organic Framework // Inorg. Chem. 2009. V. 48. P. 9980−9982.
- Tanaka D., Nakagawa K., Higuchi M., Horike S., Kubota Y., Kobayashi T. C., Takata M., Kitagawa S. Kinetic Gate-Opening Process in a Flexible Porous Coordination Polymer // Angew. Chem. Int. Ed. 2008. V. 47. P. 3914 -3918.
- Kitaura R., Seki K., Akiyama G., Kitagawa S. Porous Coordination-Polymer Crystals with Gated Channels Specific for Supercritical Gases // Angew. Chem. Int. Ed. 2003. V. 42. P. 428−431.
- Aguado S., Bergeret G., Titus M. P., Moizan V., Nieto-Draghi C., Bats N., Farrusseng D. Guest-induced gate-opening of a zeolite imidazolate framework // New J. Chem. 2011. V. 35. P. 546−550.
- Uchida S., Hashimoto M., Mizuno N. A Breathing Ionic Crystal Displaying Selective Binding of Small Alcohols and Nitriles: K3 Cr30(00CH)6(H20)3. a-SiW12040] • 16H20 // Angew. Chem. Int. Ed. 2002. V. 41. P. 2814−2817
- Chowdhury P., Mekala S., Dreisbach F., Gumma S. Adsorption of CO. C02 and CH4 on Cu-BTC and MIL-101 metal organic frameworks: Effect of open metal sites and adsorbate polarity // Microporous and Mesoporous Materials 2012. V. 152. P. 246−252.
- Chowdhury P., Bikkina C., Gumma S. Gas Adsorption Properties of the Chromium-Based Metal Organic Framework MIL-101 // J. Phys. Chem. C 2009. V. 113. P. 6616−6621.
- Kim M. J., Park S. M., Song S.-J., Won J., Lee J. Y., Yoon M., Kim K., Seo G. Adsorption of pyridine onto the metal organic framework MIL-101 // J. Colloid and Interface Science. 2011. V. 361. P. 612−617.
- Krawiec P., Kramer M., Sabo M., Kunschke R., Frode H., Kaskel S. Improved Hydrogen Storage in the Metal-Organic Framework Cu3(BTC)2 // Adv. Eng. Meter. 2006. V. 8. P. 293−296.
- Dinca M., Han W. S., Liu Y., Dailly A., Brown C. M., Long J. R. Observation of Cu2±H2 Interactions in a Fully Desolvated Sodalite-Type Metal-Organic Framework // Angew. Chem. Int. Ed. 2007. V. 46. P. 1419−1422.
- Herm Z. R., Krishna R., Long J. R. C02/CH4, CH4/H2 and C02/CH4/H2 separations at high pressures using Mg2(dobdc) // Microporous and Mesoporous Materials. 2012. V. 151. P. 481−487.
- Dinca M., Long J. R. High-Enthalpy Hydrogen Adsorption in Cation-Exchanged Variants of the Microporous Metal-Organic Framework Mn3(Mn4Cl)3(BTT)8(CH30H)10.2 // J. Am. Chem. Soc. 2007. V. 129. P. 11 172−11 176.
- Forster P. M., Eckert J., Heiken B. D., Parise J. B., Yoon J. W., Jhung S. H., Chang J.-S., Cheetham A. K. Adsorption of Molecular Hydrogen on
- Coordinatively Unsaturated Ni (II) Sites in a Nanoporous Hybrid Material // J. Am. Chem. Soc. 2006. V. 128. P. 16 846−16 850.
- Hao Z.-M., Zhang X.-M. Solvent induced molecular magnetic changes observed in single-crystal-to-single-crystal transformation // Dalton Trans. 2011. V. 40. P. 2092.
- Beauvais L. G., Shores M. P., Long J. R. Cyano-Bridged Re6Q8 (Q = S, Se) Cluster-Cobalt (II) Framework Materials: Versatile Solid Chemical Sensors // J. Am. Chem. Soc. 2000. V. 122. P. 2763−2772.
- Lloret F., Julve M., Cano J., Ruiz-Garcia R., Pardo E. Magnetic properties of six-coordinated high-spin cobalt (II) complexes: Theoretical background and its application // Inorg. Chim. Acta. 2008. V. 361. P. 3432−3445.
- Haider G. J., Kepert C. J., Moubaraki B., Murray K. S., Cashion J. D. Guest-Dependent Spin Crossover in a Nanoporous Molecular Framework Material // Science. 2002. V.298. P. 1762−1765.
- Cheng X.-N., Zhang W.-X., Lin Y.-Y., Zheng Y.-Z., Chen X.-M. A Dynamic Porous Magnet Exhibiting Reversible Guest-Induced Magnetic Behavior Modulation // Adv. Mater. 2007. V. 19. P. 1494−1498.
- Ohkoshi S., Tsunobuchi Y., Takahashi H., Hozumi T., Shiro M., Hashimoto K. Synthesis and Alcohol Vapor Sensitivity of a Ferromagnetic Copper-Tungsten Bimetallic Assembly // J. Am. Chem. Soc. 2007. V. 129. P. 3084−3085.
- Milon J., Daniel M.-C., Kaiba A., Guionneau P., Brandes S., Sutter J.-P. Nanoporous Magnets of Chiral and Racemic {Mn (HL)}2Mn{Mo (CN)7}2. with Switchable Ordering Temperatures (TC = 85 K <→ 106 K) Driven by H20
- Sorption (L = N, N-Dimethylalaninol) // J. Am. Chem. Soc. 2007. V. 129. P. 13 872−13 878.
- Kaneko Y., Kajiwara T., Yamane H., M. Yamashita Solvent induced reversible change of magnetic properties in a Fe (II)-Fe (III) single chain magnet // Polyhedron. 2007. V. 26. P. 2074−2078.
- Milon J., Guionneau P., Duhayon C., Sutter J.-P. K2Mn5{Mo (CN)7}3.: an open framework magnet with four Tc conversions orchestrated by guests and thermal history // New J. Chem. 2011. V. 35. P. 1211−1218.
- Yanai N., Kaneko W., Yoneda K., Ohba M., Kitagawa S. Reversible Water-Induced Magnetic and Structural Conversion of a Flexible Microporous Ni (II)Fe (III) Ferromagnet // J. Am. Chem. Soc. 2007. V. 129. P. 3496−3497
- Kaneko W., Ohba M., Kitagawa S. A Flexible Coordination Polymer Crystal Providing Reversible Structural and Magnetic Conversions // J. Am. Chem. Soc. 2007. V. 129. P. 13 706−13 712.
- Nowicka B., Rams M., Stadnicka K., Sieklucka B. Reversible Guest-Induced Magnetic and Structural Single-Crystal-to-Single-Crystal Transformation in Microporous Coordination Network {Ni (cyclam).3[W (CN)8]2}n // Inorg. Chem. 2007. V. 46. P. 8123−8125.
- Czaja A. U., Trukhan N., Miiller U. Industrial applications of metal-organic frameworks // Chem. Soc. Rev. 2009. V. 38. P. 1284−1293.
- Kuppler R. J., Timmons D. J., Fang Q.-R., Li J.-R., Makal T. A., Young M. D., Yuan D., Zhao D., Zhuang W., Zhou H.-C. Potential applications of metal-organic frameworks // Coord. Chem. Rev. 2009. V. 253. P. 3042−3066.
- Horcajada P., Gref R., Baati T., Allan P. K., Maurin G., Couvreur P., Ferey G., Morris R. E., Serre C. Metal-Organic Frameworks in Biomedicine // Chem. Rev. 2012. V. 112. P. 1232−1268
- Kurmoo M. Magnetic metal-organic frameworks // Chem. Soc. Rev. 2009. V.38. P. 1353−1379.
- Rocca J. D., Lin W. Nanoscale Metal-Organic Frameworks: Magnetic Resonance Imaging Contrast Agents and Beyond // // Eur. J. Inorg. Chem. 2010. P.3725−3734
- Thallapally P. K., Fernandez C. A., Motkuri R. K., Nune S. K., Peden J. L. C. H. F. Micro and mesoporous metal-organic frameworks for catalysis applications // Dalton Trans. 2010. V. 39. P. 1692−1694.
- Ravon U., Domine M. E., Gaudillere C., Desmartin-Chomel A., Farrusseng D. MOFs as acid catalysts with shape selectivity properties // New J. Chem. 2008. V. 32. P. 937−940.
- Ma L., Abney C., Lin W. Enantioselective catalysis with homochiral metal-organic frameworks // Chem. Soc. Rev. 2009. V. 38. P. 1248−1256.
- Ma S. Gas adsorption applications of porous metal-organic frameworks // Pure Appl. Chem. 2009. V. 81. P. 2235−2251.
- Jiang H.-L., Tatsu Y., Lu Z.-H., Xu Q. Non-, Micro-, and Mesoporous Metal-Organic Framework Isomers: Reversible Transformation, Fluorescence Sensing, and Large Molecule Separation // J. Am. Chem. Soc. 2010. V. 132. P. 55 865 587.
- Chen B., Xiang S., Qian G. Metal-Organic Frameworks with Functional Pores for Recognition of Small Molecules // Acc. Chem. Res. 2010. V. 43, No. 8. P. 1115−1124.
- Peralta D., Chaplais G., Simon-Masseron A., Barthelet K., Chizallet C., Quoineaud A.-A., Pirngruber G. D. Comparison of the Behavior of Metal. Organic Frameworks and Zeolites for Hydrocarbon Separations // J. Am. Chem. Soc. 2012. V. 134. P. 8115−8126.
- Xiong R.-G., You X.-Z., Abrahams B. F., Xue Z., Che C.-M. Enantioseparation of Racemic Organic Molecules by a Zeolite Analogue // Angew. Chem. Int. Ed. 2001. V. 40. P. 4422−4425.
- Seo J. S, Whang D., Lee H., Jun S. I., Oh J., Jeon Y. J., Kim K. A homochiral metal-organic porous material for enantioselective separation and catalysis // Nature. 2000. V. 404. P. 982−986.
- Achmann S., Hagen G., Hammerle M., Malkowsky I., Kiener C., Moos R. Sulfur Removal from Low-Sulfur Gasoline and Diesel Fuel by Metal-Organic Frameworks // Chem. Eng. Technol. 2010. V. 33. P. 275−280.
- Han S., Wei Y., Valente C., Lagzi I., Gassensmith J. J., Coskun A., Stoddart J. F., Grzybowski B. A. Chromatography in a Single Metal-Organic Framework (MOF) Crystal//J. Am. Chem. Soc. 2010. V. 132. P. 16 358−16 361.
- Gu Z.-Y., Yang С.-Х., Chang N., Yan X.-P. Metal-Organic Frameworks for Analytical Chemistry: From Sample Collection to Chromatographic Separation // Acc. Chem. Res. 2012. V. 45, No. 5. P. 734−745.
- Rosi N. L., Eckert J., Eddaoudi M., Vodak D. Т., Kim J., O’Keeffe M, Yaghi О. M. Hydrogen Storage in Microporous Metal-Organic Frameworks // Sceince. 2003. V. 300. P. 1127−1129.
- Jacoby M. // Chem. Eng. News. 2005. V. 22. P. 42.
- Ztittel A. Materials for hydrogen storage // Materials Today. 2003. V. 6. P. 2433.
- Sheldrick G. М. SHELX-97. Gottingen, Germany: University of Gottingen, 1997.
- Kahn O. Molecular Magnetism. Weinheim, Germany: Wiley-VCH, 1993.
- Михайлова Т. Б., Малков А. Е., Сидоров А. А., Александров Г. Г., Голованева И. Ф., Демьянович В. М., Новоторцев В. М., Икорский В. Н., Нефедов С. Е., Еременко И. JI. // Журн. неорг. химии. 2002. Т. 47. № 9, С. 1829−1839.
- Сидоров А. А. Полиядерные триметилацетаты никеля и кобальта: магнитноактивные кластеры и модели металлоферментов: дисс. докт. хим. наук: 02.00.01 / Ин-т общей и неорг. химии РАН. Москва, 2002. 221 с.
- Фомина И. Г., Сидоров А. А., Александров Г. Г., Жилов В. И., Икорский В. Н., Новоторцев В. М., Еременко И. Л., Моисеев И. И. Несимметричные биядерные пивалатные комплексы с атомами кобальта и никеля // Изв. АН. Сер. хим. 2004. С. 116−123.
- Еременко И. JL, Голубничая М. А., Нефедов С. Е., Сидоров А. А., Голованоева И. Ф., Бурков В. И., Эллерт О. Г., Новоторцев В. М., Еременко JI. Т., Соуса А., Бермежо М. Р. // Изв. АН. сер. хим. 1998. С. 725.
- Талисманова М. О., Сидоров А. А., Новоторцев В. М., Александров Г. Г., Нефедов С. Е., Еременко И. Л., Моисеев И. И. // Изв. АН. Сер. хим. 2001. С. 2149.
- Кискин М.А. Магнитноактивные полимерные пивалаты марганца(Н) и железа (П): синтез, строение, магнитные свойства и химическая активность: дисс. канд. хим. наук: 02.00.01 / Ин-т общей и неорг. химии РАН. Москва, 2005. 150 с.
- Пахмутова Е. В., Сидоров А. А., Фомина И. Г., Александров Г. Г.,
- Новоторцев В. M., Икорский В. Н., Еременко И. JL Новые триметилацетатные комплексы кобальта с пиридином // Изв. АН. Сер. хим. 2003. С. 2013.
- Заузолкова Н. В., Никифорова M. Е., Кискин М. А., Богомяков А. С., Сидоров А. А., Еременко И. Л. Образование гетерометаллических пиридонатно-карбоксилатных координационных полимеров с атомами кобальта и лития // Изв. АН. Сер. хим. 2011. С. 267−273.
- Kiskin M. A., Fomina I. G., Aleksandrov G. G., Sidorov A. A., Novotortsev V. M., Shvedenkov Y. G., Eremenko I. L., Moiseev I. I. First triangular carboxylate cluster with the Fe (II)Fe (II)Fe (II) metal core // Inorg.Chem.Сommun. 2004. V. 7. P. 734−736.
- Сидоров A. A., Фомина И. Г., Талисманов С. С., Александров Г. Г., Новоторцев В. М., Нефедов С. Е., Еременко И. Л. Превращения полиядерных гидроксо- и оксотриметилацетатных комплексов Ni(II) и Со (И) // Коорд. химия. 2001. Т. 27. С. 548−559.
- Голубничая М. А., Сидоров А. А., Фомина И. Г., Понина М. О., Деомидов С. М., Нефедов С. Е., Еременко И. Л., Моисеев И. И. // Изв. АН. Сер. хим. 1999. С. 1773.
- Малков А. Е., Михайлова Т. Б., Александров Г. Г., Пахмутова Е. В., Егоров И. М., Сидоров А. А., Фомина И. Г., Нефедов С. Е., Еременко И. Л., Моисеев И. И. // Изв. АН. Сер. хим. 2001. С. 2370−2372.
- Kiskin M. A., Aleksandrov G. G., Ikorskii V. N., Novotortsev V. M., Eremenko I. L. First Hexanuclear Manganese (II) ц6-С1 Centered Carboxylate Anion:
- Synthesis, Structure and Magnetic Properties // Inorg. Chem. Commun. 2007. V. 10. P. 997−1000.
- Kiskin M. A., Aleksandrov G. G., Bogomyakov A. S., Novotortsev V. M., Eremenko I. L. Coordination polymers of cobalt (II) with pyrimidine and pyrazine: Syntheses, structures and magnetic properties // Inorg. Chem. Commun. 2008. V. 11. P. 1015−1018.
- Денисова Т. О., Алекснадров Г. Г., Фиалковский О. П., Нефедов С. Е. // Журн. неорг. химии. 2003. Т. 48. С. 1340−1349.
- Karmakar A., Sarma R. J., Baruah J. B. Mechanochemical Control of Synthesis and Structures of Aqua-Bridged Binuclear Nickel (II) Benzoate Complexes // Eur. J. Inorg. Chem. 2006. P. 4673−4678.
- Karmakar A., Deka K., Sarma R. J., Baruah J. В., Benzoic acid inclusion in a dimeric nickel complex and its catalytic activity // Inorg. Chem. Commun. 2006. V. 9. P. 836−838.
- Turpeinen U. //Finn. Chem. Lett. 1977. P. 36−41.
- Turpeinen U. // Finn. Chem. Lett. 1977. P. 123−128.
- Ahlgren M., Hamalainen R., Turpeinen U. Cryst. Struct. Commun. 1977. V.6. P. 829−834.
- Song W.-D., Yan J.-B., Hao X.-M. mu.-Aqua-[kappa]20:0-di-[mu]-4-methy lbenzoato- [kappa]40:0'-bis [(4-methy lbenzoato-[kappa] 0)(1,10-phenanthroline-[kappa]2N, N')nickel (II)] // Acta Crystallogr., Sect. E. 2008. V. E64. P. m919-m920.
- Chen Z.-F., Zhang S.-F., Luo H.-S., Abrahams B. F., Liang H., Ni2(R*C00)4(H20)(4,4-bipy)2—a robust homochiral quartz-like network with large chiral channels // Cryst. Eng. Commun. 2007. V. 9. P. 27−29.
- Baikie A. R., Howes A. J., Hursthouse M. В., Quick А. В., Thornton P., Preparation, crystal structure, magnetic properties, and chemical reactions of a hexanuclear mixed valence manganese carboxylate // J. Chem. Soc., Chem. Commun. 1986. P. 1587.
- Koehler K., Roesky H. W., Noltemeyer M., Schmidt H.-G., Freire-Erdbruegger C., Sheldrick G. M. // Chem. Ber. 1993. V. 126. P. 921−926.
- Murrie M., Parsons S., Winpenny R.E.P., Deltahedra as underlying structural motifs in polynuclear metal chemistry: structure of an undecanuclear manganese-potassium cage // J. Chem. Soc., Dalton Trans. 1998. P. 1423−1424.
- Nakata K., Miyasaka H., Sugimoto K., Ishii Т., Sugiura K., Yamashita M. Construction of a One-Dimensional Chain Composed of Mn6 Clusters and 4,4'-Bipyridine Linkers: The First Step for Creation of «Nano-Dots-Wires» // Chem. Lett. 2002. P. 658−659.
- Пасынский А.А., Идрисов Т. Ч., Суворова К. М., Новоторцев В. М., Калинников В. Т. // Докл. АН СССР. 1975. Т. 220, № 4. С. 881−883.
- ПасынскиЙ А.А., Идрисов Т. Ч., Суворова К. М., Новоторцев В. М., Калинников В. Т. // Коорд. химия. 1975. Т. 1, № 6. С. 799−803.
- ПасынскиЙ А.А., Идрисов Т. Ч., Суворова К. М., Калинников В. Т. // Коорд. химия. 1976. Т. 2, № 8. С. 1060−1068.
- Eddaoudi M., Moler D. В., Li H., Chen В., Reineke T. M., O’Keeffe M., Yaghi О. M. Reticular synthesis and the design of new materials // Acc. Chem. Res. 2001. V. 34. P. 319−330.
- Nukada R., Mori W., Takamizawa S., Mikuriya M., Handa M., Naono H. Microporous Structure of a Chain Compound of Copper (II) Benzoate Bridged by Pyrazine // Chem. Lett. 1999. V. 5. P. 367−368.
- Peedikakkal A. M. P., Song Y.-M., Xiong R.-G., Gao S., Vittal J. J. Cobalt (II) Coordination Polymers Containing trans-l, 2-Bis (4-pyridyl)ethene and Their Magnetic Properties // Eur. J. Inorg. Chem. 2010. P. 3856- 3865.
- Хим. 2010. № 6. С. 1192−1198.
- Spek A. L. PLATON, An Integrated Tool for the Analysis of the Results of a Single Crystal Structure Determination // Acta Crystallogr., Sect. A. 1990. V. A46 (Supplement). C34
- Coles M. P. Copper // Annu. Rep. Prog. Chem., Sect. A: Inorg. Chem. 2012. V. 108. P. 220−229.
- Ohmori O., Kawano M., Fujita M. Construction of biporous coordination networks via к-к interaction // Cryst. Eng. Commun. 2005. V. 7. P. 255−259.
- Gregg S. J. Adsorption, Surface Area and Porosity, Second Edition, S.J. Gregg, K.S.W. Sing. Academic Press, 1982.
- Reimers J. N., Dahn J. R. Electrochemical and In Situ X-Ray Diffraction Studies of Lithium Intercalation in LixCo02 // J. Electrochem. Soc. 1992. V. 139. P. 2091−2097.
- Wang M., Navrotsky A. LiM02 (M=Mn, Fe, and Co): Energetics, polymorphism and phase transformation // J. Sol. State Chem. 2005. V. 178. P. 1230−1240.
- Fry сек R., Vyslouzil F., Myslik V., Vrnata M., Kopecky D., Ekrt O., Fitl P., Jelinek M., Kocourek Т., Sipula R. Deposition of organic metalocomplexes for sensor applications by MAPLE // Sens. Actuators, B. 2007. V. 125. P. 189−194.
- Thakuria H., Borah B.M., Das G. ZnO Nano Particles from Metal-Organic
- Framework of Zn (II) — Metallacycles // Eur. J. Inorg. Chem. 2007. P. 524−529.
- Condorelli G. G., Malandrino G., Fragala I. L. Engineering of molecular architectures of P-diketonate precursors toward new advanced materials // Coord. Chem. Rev. 2007. V. 251. P. 1931−1950.
- Stefanescu M., Stefanescu O., Stoia M., Lazau C. Thermal decomposition of some metal-organic precursors // J. Therm. Anal. Cal. 2007. V. 88. P. 27−32.
- Revaprasadu N., Mlondo S. N. Use of metal complexes to synthesize semiconductor nanoparticles // Pure Appl. Chem. 2006. V. 78. P. 1691−1702.
- Sabo T. J., Grguric-Sipka S.R., Trifunovic S.R. Transition metal complexes with edda-type ligands. Synth. React // Inorg. Met. Org. Chem. 2002. V. 32. P. 1661−1717.
- Deb N., Baruah S. D., Dass N. N. Synthesis, Characterization and Thermal Decomposition of MlM2(C204)2.xH20 (x=5 for Ml=Co and x=4 for Ml=Cd. M2=Ni) // J. Therm. Anal. Calorim. 2000. V. 59. P. 791−797.
- Wullens H., Bodart N., Devillers M. New Bismuth (III), Lanthanum (III), Praseodymium (III), and Heterodinuclear Bi-La and Bi-Pr Complexes with Polyaminocarboxylate Ligands // J. Solid State Chem. 2002. V. 167. P. 494 507.
- Blake A. B., Yavari A., Hatfield W. E., Sethulekshmi C. N. Magnetic and spectroscopic properties of some heterotrinuclear basic acetates of chromium (III), iron (III) and divalent metal ions // J. Chem. Soc., Dalton Trans. 1985. No. 12. P. 2509−2520.
- Blake A. B., Yavari A., Kubicki H. Exchange interactions in a series of novel heteronuclear basic carboxylate complexes containing two iron (III) ions and a divalent metal ion // J. Chem. Soc., Chem. Commum. 1981. P. 796−797.
- Polunin R. A., Kiskin M. A., Cador O., Kolotilov S. V. Coordination polymers based on trinuclear heterometallic pivalates and polypyridines: synthesis, structure, sorption and magnetic properties // Inorg. Chim. Acta, 2012, V. 380. P. 201−210.
- Singh, B., Long, J. R., Papaefthymiou, G. C., Stavropoulos, P. On the Reduction of Basic Iron Acetate: Isolation of Ferrous Species Mediating Gif-Type Oxidation of Hydrocarbons // J. Am. Chem. Soc. 1996. V. 118. P. 5824−5825.
- Sato T., Ambe F., Endo K., Katada M., Sano H. Crystal structures and Mossbauer spectroscopic studies of oxo-centered trinuclear chloroacetate complexes // J. Radioanalytical Nucl. Chem. 1995. V. 190. P. 257−261.
- Shova S., Prodius D., Mereacre V., Simonov Y. A., Lipkowski J., Turta C. Discernible apical coordination in |j.3-oxo-bridged mixed metal trinuclear carboxylate Fe2Mn0(CHC12C00)6(THF)2H20. // Inorg. Chem. Commun. 2004. V. 7. P. 292−295.
- Ng. S. W. Aquabis (tetrahydrofuran)hexakis (trichloroacetato)copper (II) diiron (III) hexane solvate // Acta Crystallogr., Sect. E: Struct. Rep. Online. 2004. V. 60. P. m738-m740.
- Turta C., Shova S., Prodius D., Mereacre V., Gdaniec M., Simonov Y., Lipkowski J. Novel heteronuclear image-bridged trichloroacetates: synthesis and X-ray study of image and image // Inorg. Chim. Acta. 2004. V. 357. P. 4396−4404.
- Clegg W., Lam O. M., Straughan B. P. Structure of a Novel i3-Oxo-Femath imageCrlll-Glycine Complex // Angew. Chem., Int. Ed. 1984. V. 23. P. 434 435.
- Nakamoto Т., Hanaya M., Katada M., Endo К., Kitagawa S., Sano H. The Valence-Detrapping Phase Transition in a Crystal of the Mixed-Valence Trinuclear Iron Cyanoacetate Complex Fe30(02CCH2CN)6(H20)3. // Inorg. Chem. 1997, V. 36. P. 4347−4359.
- Cui Y, Zhang L.-N., Huang X.-Y., He L.-J., Wang Y.-M., Cai S.-H., Chen B. // Jiegou Huaxue. (Chin. J. Struct. Chem.) 1997. V. 16. P. 247.
- Бацанов А. С., Тимко Г. А., Стучков Ю. Т., Гербелеу Н. В., Маноле О. С. // Коорд. химия. 1991. Т. 17. 922.
- Breeze, В. A., Shanmugam, М., Tuna, F., Winpenny, R. Е. P. A series of nickel phosphonate-carboxylate cages // Chem. Commun. 2007. P. 5185−5187.
- Bagai R., Christou G. The Drosophila of single-molecule magnetism: Mn12012(02CR)i6(H20)4. // Chem. Soc. Rev. 2009. V. 38. P. 1011−1026.
- Mironov V.S. Strong exchange anisotropy in orbitally degenerate complexes. A new possibility for designing single-molecule magnets with high blocking temperatures // J. Magn. Magn. Mater. 2004. V. 272−276. P. e73 l-e733.
- Baskar V., Gopal K., Helliwell M., Tuna F., Wernsdorfer W., Winpenny R.E.P. 3d-4f Clusters with large spin ground states and SMM behaviour // Dalton Trans. 2010. V. 39. P. 4747^1750.
- Миронов B.C. Тригонально-бипирамидальные спиновые кластеры с1.I 3орбитально-вырожденными 5d-unaHOKOMmieKcaMH Os (CN)6. ' -прототипы высокотемпературных мономолеклярных магнитов // Доклады АН. Физ. Хим. 2007. Т. 415, № 3ю С. 357−363ю
- Ishikawa N., Sugita M., Ishikawa T., Koshihara S., Kaizu Y. Lanthanide Double-Decker Complexes Functioning as Magnets at the Single-Molecular Level // J. Am. Chem. Soc. 2003. V. 125. P. 8694−8695.
- Gomez-Segura J., Diez-Perez I., Ishikawa N., Nakano M., Vecianaa J., Ruiz-Molina D. 2-D Self-assembly of the bis (phthalocyaninato)terbium (III) single-molecule magnet studied by scanning tunnelling microscopy // Chem. Commun. 2006. P. 2866−2868.
- Branzoli F., Carretta P., Filibian M., Zoppellaro G., Graf M.J., Galan-Mascaros J.R., Fuhr O., Brink S., Ruben M. Spin Dynamics in the Negatively Charged Terbium (III) Bis-phthalocyaninato Complex // J. Am. Chem. Soc. 2009. V. 131. P. 4387−4396k)
- Bencini A., Benelli C., Caneschi A., Carlin R.L., Dei A., Gatteschi D. Crystal and molecular structure of and magnetic coupling in two complexes containing gadolinium (III) and copper (II) ions // J. Am. Chem. Soc. 1985. V. 107. P. 81 288 136.
- Sessoli R., Gatteschi D., Caneschi A., Novak M. A. Magnetic bistability in a metal-ion cluster//Nature. 1993. V. 365. P. 141−143.
- Osa S., Kido T., Matsumoto N., Re N., Pochaba A., Mrozinski J. A Tetranuclear3d-4f Single Molecule Magnet: CunLTbm (hfac)2.2 // J- Am. Chem. Soc. 2004. V. 126. P. 420−421.
- Zaleski C. M., Depperman E. C., Kampf J. W., Kirk M. L., Pecoraro V. L. Synthesis, Structure, and Magnetic Properties of a Large Lanthanide-Transition-Metal Single-Molecule Magnet // Angewandte Chemie International Edition. 2004. V. 43. P. 3912−3914.
- Mishra A., Wernsdorfer W., Parsons S., Christoua G., Brechin E.K. The search for 3d-4f single-molecule magnets: synthesis, structure andmagnetic properties of a Mnni2Dyni2. cluster// Chem. Commun. 2005. P. 2086−2088.
- Benelli C., Murrie M., Parsons S., Winpenny R.E.P. Mn-Gd pivalate: preparation from a pre-formed hexanuclearcluster // J. Chem. Soc., Dalton Trans. 1999. P. 4125−4126.
- Mishra A., Wernsdorfer W., Abboud K.A., Christou G. Initial Observation of Magnetization Hysteresis and Quantum Tunneling in Mixed Manganese-Lanthanide Single-Molecule Magnets // J. Am. Chem. Soc. 2004. V. 126. P. 15 648−15 649.
- Ako A. M., Mereacre V., Cle’rac R., Wernsdorfer W., Hewitt I. J., Ansona C. E., Powell A. K. A Mn18Dy. SMM resulting from the targeted replacement of the centralMnll in the S = 83/2 [Mnl9]-aggregate with Dylll // Chem. Commun. 2009. P. 544−546.
- Li M., Ako A.M., Lan Y., Wernsdorfer W., Buth G., Anson C.E., Powell A.K., Wang Z., Gao S. New heterometallic MnIU4Lnin4. wheels incorporating formate ligands // Dalton Trans. 2010. P. 3375−3377.
- Langley S. K., Moubaraki B., Murray K. S. A heptadecanuclear Mn1II9Dyin8 cluster derived from triethanolamine withtwo edge sharing supertetrahedra as the core and displaying SMM behavior // Dalton Trans. 2010. P. 5066−5069.
- Hatscher S. T., Urland W. Unexpected Appearance of Molecular Ferromagnetism in the Ordinary Acetate {Gd (0Ac)3(H20)2}2.4H20 // Angewandte Chemie International Edition. 2003. V. 42. P. 2862−2864.
- Benelli C., Fabretti A.C., Giusti A. Synthesis, molecular structure, and magnetic properties of a Cu2Gd complex // J. Chem. Soc., Dalton Trans. 1993. P. 409 412.
- Costes J.-P., Dahan F., Dupuis A., Laurent J.-P. Is Ferromagnetism an Intrinsic
- Property of the Cun/Gdm Couple? 1. Structures and Magnetic Properties of Two Novel Dinuclear Complexes with a jx-Phenolato-ji-Oximato (Cu, Gd) Core //Inorg. Chem. 2000. V. 39. P. 169−173.
- Ryazanov M., Nikiforov V., Lloret F., Julve M., Kuzmina N., Gleizes A.
- Magnetically Isolated CuIlGdl" Pairs in the Series Cu (acacen)Gd (pta)3., [Cu (acacen)Gd (hfa)3], [Cu (salen)Gd (pta)3], and [Cu (salen)Gd (hfa)3], [acacen = N, N'-Ethylenebis (acetylacetoniminate (-)), salen = N, N'
- Ethylenebis (salicylideniminate (-)), hfa = l, l, l, 5,5,5-Hexafluoropentane-2,4-dionate (-), pta = l, l, l-Trifluoro-5,5-dimethylhexane-2,4-dionate (-). // Inorg. Chem. 2002. V. 41. P. 1816−1823.
- Yamaguchi T., Sunatsuki Y., Kojima M., Akashi H., Tsuchimoto M., Re N., Osae S., Matsumoto N. Ferromagnetic Ni'-Gd1″ interactions in complexes with NiGd, NiGdNi, and NiGdGdNi cores supported by tripodal ligands // Chem. Commun. 2004. P. 1048−1049.
- Akine S., Matsumoto T., Taniguchi T., Nabeshima T. Synthesis, Structures, and Magnetic Properties of Tri- and Dinuclear Copper (II)-Gadolinium (III) Complexes of Linear Oligooxime Ligands // Inorg. Chem. 2005. V. 44. P. 32 703 274.
- BingWu W., ShangDa J., XiuTeng W., Song G. Magnetic molecular materials with paramagnetic lanthanide ions // Sci. China, Ser. B-Chem. 2009. V. 52. P. 1739−1758.
- Cui Y., Chen G., Ren J., Qian Y., Huang J. Syntheses, Structures and Magnetic Behaviors of Di- and Trinuclear Pivalate Complexes Containing Both Cobalt (II) and Lanthanide (III) Ions // Inorg. Chem. 2000. V. 39. P. 4165−4168.
- Parsons S., Tan X., Winpenny R., Wood P. // Private Commun. 2004. CCDC 248 070.
- Cui Y., Chen J.-T., Long D.-L., Zheng F.-K., Cheng W.-D., Huang J.-S. Preparation, structure and preliminary magnetic studies of tri- and tetra-nuclear cobalt-lanthanide carboxylate complexes // J. Chem. Soc., Dalton Trans. 1998. P.2955−2956.
- Izarova N. V., Sokolov M. N., Rothenberger A., Ponikiewski L., Fenske D.,
- Fedin V. P. Synthesis and crystal structure of a new metal-organic coordination polymer Fe (4,4'-bpy)3(H20)2.(PF6)2(4,4'-bpy)-5H20 with nanosized channels clathrate large organic molecules // C. R. Chimie. 2005. V. 8. P. 10 051 010.
- Likhtenshtein G. Stilbenes. Applications in Chemistry, Life Sciences and Materials Science. Weinheim, Germany: Wiley-VCH, 2009.
- Duan Z., Zhang Y., Zhang B., Pratt F. L. Two Homometallic Antiferromagnets Based on Oxalato-Bridged Honeycomb Assemblies: (A^M^^O^. (A = Ammonium Salt Derived from Diethylenetriamine. M11 = Fe2+, Co2+) // Inorg. Chem.2009. V.48. P. 2140−2146.
- Wang X.-T., Wang Z.-M., Gao S. Honeycomb Layer of Cobalt (II) Azide Hydrazine Showing Weak Ferromagnetism // Inorg. Chem. 2007. V.46. P.10 452−10 454.
- Sun Q.-F., Iwasa J., Ogawa D., Ishido Y., Sato S., Ozeki T., Sei Y., Yamaguchi K., Fujita M. Self-Assembled M24L48 Polyhedra and Their Sharp Structural Switch upon Subtle Ligand Variation // Science. 2010. V. 328. P. 1144−1147.
- Fujita M., Umemoto K., Yoshizawa M., Fujita N., Kusukawa T., Biradha K. Molecular paneling via coordination // Chem. Commun. 2001. P. 509−518.
- Park J., Hong S., Moon D., Park M., Lee K., Kang S., Zou Y., John R. P., Kim
- Suzuki K., Tominaga M., Kawano M., Fujita M. Self-assembly of an M6L12 coordination cube //Chem. Commun. 2009. P. 1638−1640.
- Wu J.-Y., Lin Y.-F., Chuang C.-H., Tseng T.-W., Wen Y.-S., Lu K.-L. Ag4L2 Nanocage as a Building Unit toward the Construction of Silver Metal Strings // Inorg. Chem. 2008. V. 47. P. 10 349−10 356.
- Zhang Q., Jiang F., Huang Y., Wu M., Hong M. Coordination-Driven Face-Directed Self-Assembly of a M9L6 Hexahedral Nanocage from Octahedral Ni (II) Ions and Asymmetric Hydrazone Ligands // Crystal Growth & Design. 2009. V. 9. P. 28−31.
- Kuang X., Wu X., Yu R., Donahue J. P., Huang J., Lu C.-Z. Assembly of a metal-organic framework by sextuple intercatenation of discrete adamantane-like cages. Nature Chemistry. 2010. V. 2. P. 461−465.
- Park S.-K., Min K.-C., Lee C., Hong S. K., Kim Y" Lee N.-S. Intermolecular Hydrogen Bonding and Vibrational Analysis of N, N-Dimethylformamide Hexamer Cluster // Bull. Korean Chem. Soc. 2009. V. 30. P. 2595−2602
- Decurtins S., Schmalle H. W., Oswald H. R., Linden A., Ensling J., Gutlich P., Hauser A. A polymeric two-dimensional mixed-metal network. Crystal structure and magnetic properties of {P (Ph)4. MnCr (ox)3]} // Inorg. Chim. Acta. 1994. V. 216. P. 65−73.
- Miller J. S., Drillon M. Magnetism: Molecules to Materials II. Weinheim, Germany: Wiley-VCH, 2002.
- Gatteschi D., Sessoli R., Villain J. Molecular nanomagnets. New York: Oxford University Press, 2006.
- Ostrovsky S.M., Werner R., Brown D.A., Haase W. Magnetic properties of dinuclear cobalt complexes // Chem. Phys. Lett. 2002. V. 353. P. 290−294.
- Карлин P. Магнетохимия. Москва: Мир, 1989.
- Borres-Almenar J. J., Clemente-Juan J. M., Coronado E., Lloret F. Alternating antiferromagnetic and ferromagnetic exchange interactions in the S = 1 Heisenberg chain. Theory and magnetic properties // Chem. Phys. Lett. 1997. V. 275. P. 79−84.
- Maji Т. K., Laskar I. R., Mostafa G., Welch A. J., Mukherjee P. S., Chaudhuri N. R. A ID thiocyanato bridge nickel (II) system: crystal structure and magnetic property// Polyhedron. 2001. V. 20. P. 651−655.
- Schlam R. F., Perec M., Calvo R., Lezama L., Insausti M., Rojo Т., Foxman В.
- M. Structure and magnetic properties of binuclear Cu2(02CCHCHCH3)4(DMF)2: a carboxylate-bridged Cu (II) spin dimer 11 Inorg. Chim. Acta. 2000. V. 310. P.81−88.
- Reger D. L., Debreczeni A., Smith M. D. Copper (II) Carboxylate Dimers Prepared from Ligands Designed to Form a Robust n—n Stacking Synthon: Supramolecular Structures and Molecular Properties // Inorg.Chem. 2012. V. 51. P. 1068−1083.
- Sinn. E. Magnetic exchange in polynuclear metal complexes // Coord. Chem. Rev. 1970. V. 5. P. 313−347.
- Mironov V. S., Chibotaru L. F., Ceulemans A. The origin of a strong Yb3±Cr3+ exchange anisotropy // Phys. Rev. B. 2003. V. 67. P. 14 424−14 424.
- Albores P., Rentschler E. Rational design of covalently bridged Feni2MnO. clusters // Dalton Trans., 2010. V. 39. P. 5005−5019.
- Ginsberg A. P., Lines M. E. Magnetic exchange in transition metal complexes. VIII. Molecular field theory of intercluster interactions in transition metal cluster complexes // Inorg. Chem. 1972. V. 11. P. 2289−2290.
- Калинников B.T., Ракитин Ю. В. Введение в магнетохимию. Москва: Наука, 1980.
- Cirera J., Ruiz Е. Exchange coupling in CuIIGdIII dinuclear complexes: A theoretical perspective // C. R. Chimie. 2008. V. l 1. P. 1227−1234.
- Здесь и далее, нагревание растворов проводилась на водяной бане с использованием стандартной шленк-технологии и вакуума водоструйного насоса.
- Здесь и далее, растворы реакционных смесей концентрировали в вакууме водоструйного насоса на водяной бане с использованием стандартной шленк-технологии.
- Со (|.-Р1у)2(ц-4-р1г)(г]-ЕЮН)2]п (3.13). Соединение получено аналогично комплексу 3.14. соединения 3.13 0.148 г (70% в пересчете на Найдено (%):
- С, 57.59- H, 6.41- N, 12.35. Вычислено для C32CoH42N606 (%): С, 57.76- H, 6.36- N, 12.62.
- Ni2Sm (Piv)6(NOз)(HPiv)2(MeCN)2.•MeCN (3.46). Комплекс 3.46 был получен по методике аналогичной синтезу 3.44 с использованием 8 т (ТчЮз)з-6Н20.
- Со2Ьа (Р1у)б (Ж)з)(МеСМ)2.: Выход 35%. Найдено (%): С, 40.6- Н, 6.2- N. 4.0- Со, 11.7- Ьа, 13.7. С34Со2Н6оЬаН3015. Вычислено (%): С, 40.53- Н, 6.00- N. 4.17- Со, 11.70- Ьа, 13.79.
- Со2Се (Р1у)6(Ж)з)(МеСК)2.: Выход 34%. Найдено (%): С, 40.3- Н, 6.1- N. 4.1- Со, 11.7- Се, 13.9. С34Со2Н6оСеМз015. Вычислено (%): С, 40.48- Н, 5.99- N. 4.17- Со, 11.68- Се, 13.89.
- Со2Рг (Р1у)60ЧЮ3)(МеСМ)2.: Выход 36%. Найдено (%): С, 40.5- Н, 5.8- N. 4.0- Со, 11.6- Рг, 14.90. С34Со2НбоРгМз015. Вычислено (%): С, 40.45- Н, 5.99- N. 4.16- Со, 11.67- Рг, 13.96.
- Со2Ш (Р1у)6(ТчЮз)(МеС>02.: Выход 35%. Найдено (%): С, 40.2- Н, 5.6- N. 4.0- Со, 11.6- N (1, 14.2. Сз4Со2Н60Нс1МзО15. Вычислено (%): С, 40.31- Н, 5.97- N. 4.15- Со, 11.64- N (1, 14.24.
- Со2Еи (Р1у)6(Ж)зХМеС>Г)2.: Выход 37%. Найдено (%): С, 40.1- Н, 5.8- И, 3.9- Со, 11.6- Ей, 14.8. С34Со2Н6оЕиМз015. Вычислено (%): С, 40.01- Н, 5.93- N. 4.12- Со, 11.55- Ей, 14.89.
- Со2Ос1(Р1у)6(1чЮз)(МеСЫ)2.: Выход 38%. Найдено (%): С, 39.7- Н, 5.6- N. 4.0- Со, 11.4- вд, 15.3. С34Со2Н6оОёНз015. Вычислено (%): С, 39.80- Н, 5.89- N. 4.10- Со, 11.49- вё, 15.33.
- Co2Gd (Piv)6(N03)(4-(NH2)C5H4N)2.-2MeCN получен по методике, аналогичной синтезу комплекса Co2Nd (Piv)6(N03)(4-(NH2)C5H4N)2]-2MeCN из
- Выход--80%. ИК-спектр полученной твердой фазы идентичен спектрукомплекса Co2Nd (Piv)6(N03)(4-(NH2)C5H4N)2.-2MeCN.
- ИК-спектр (КВг) у/см"1: 3404 ш. ср, 3372 ср, 3296 ср, 2960 ср, 2932 ср, 2872 сл, 1664 сл, 1652 сл, 1632 ср, 1584 с, 1520 ср, 1484 ср, 1456 сл, 1424 с, 1376 ср, 1360 ср, 1308 сл, 1228 ср, 1196 сл, 1076 сл, 1032 сл, 900 ср, 788 ср, 620 ср, 568 ср, 440 ср.
- Со2Сс!(Р1у)б (.>Юз)(1т)2] получен по методике, аналогичной синтезу комплекса Со28т (Р1у)6(Ж)з)(1т)2 из 3.57. Выход 87%. ИК-спектр полученной твердой фазы идентичен спектру комплекса Со28т (Р1у)6(1чЮ3)(1т)2.
- СогЕ^Ргу^ГЮзХг^'-Ьру)!. получен по методике, аналогичной синтезу комплекса Со2Еи (Р1 у)6(Н03)(2,2'-Ьру)2] из 3.57. Выход 80%. ИК-спектр полученной твердой фазы идентичен спектру комплекса Со2Еи (Р1у)6(Ж)з)(2,2'1. Ьру)2
- Со2Сс!(Р1у)б (.ЧОз)(ц.-ВАВСО)]" был получен по методике, аналогичной синтезу комплекса 3.64 из 3.57. Выход 90%. ИК-спектр полученной твердой фазы идентичен спектру комплекса 3.64.
- Со2Сс1(Р1у)б (.ЧОз)(|л-с1атЬ)]" был получен по методике, аналогичной синтезу комплекса 3.65 из 3.57. Выход 80%. ИК-спектр полученной твердой фазы идентичен спектру комплекса 3.65.
- Ре21ЧЮ (Р1у)б (ВМР)з. (3.67). Комплекс получали путем кристаллизации Ре2№ 0(Р1у)б (НР1у)3 из ДМФА. Выход в разных синтезах был в пределах от 80 до 90%.
- Ре2СоО (Р1у)6(Ьре1:)2." (3.74). Соединение получено по методике, аналогично синтезу 3.73. Выход 0.072 г (68%). Найдено (%): С, 52.6- Н, 6.58- N. 5.04. Вычислено для Ре2СоС51Н76Ы4014 (%): С, 53.7- Н, 6.67- N. 4.92.
- Fe2NiO (Piv)6(444py3py)1.25H200.75DMF.n (3.78 1.25H200.75DMF).
- Fe2C0O (Piv)6(444py3py)1.25H2O-3DMF." (3.791.25H20−3DMF).
- Fe2CoO (Piv)6(4-ptz)." (3.80). Соединение было получено по методике, аналогичной получению 3.81 из 3.26. Выход 0.45 г (80%). Найдено (%): С, 51.9- Н, 6.04, N, 7.50. Вычислено для Fe2CoC48H66N6013 (%): С, 52.1- Н, 6.02- N, 7.60.
- Ее2СоО (Р1у)б (3-р1г).п (3.85). Методика синтеза 3.85 аналогична получению3.80, вместо 4-р1г был использован (0.156 г, 0.5 ммоль). Выход 0.492 г (89%). Найдено (%): С, 52.2- Н, 6.02, N. 7.48. Вычислено для Ре2СоС48Н66^С>1з (%): С, 52.1- Н, 6.02- N, 7.60.