Различные морфологии металлополимерных систем и их влияние на свойства нанокомпозитов тема диссертации и автореферата по ВАК РФ 02.00.06, кандидат химических наук Цветкова, Ирина Борисовна

В последние годы наблюдается взрыв интереса к созданию и исследованию наноразмерных структур, т.е. структур, чьи размеры находятся в диапазоне примерно от 1 до 100 нм. Частицы нанометровых размеров проявляют особые свойства, отличные от свойств аналогичных массивных материалов: механические, оптические, электрические, каталитические и магнитные. Одной из главных причин изменения физических и химических свойств малых частиц по мере уменьшения их размеров является возрастание в них относительной доли поверхностных атомов, находящихся в иных условиях (координационное число, симметрия локального окружения и т.д.), чем атомы в объеме материала. С энергетической точки зрения уменьшение размеров частиц приводит к возрастанию доли поверхностной энергии в ее химическом потенциале.

Бурное развитие этой области науки привело к возникновению совершенно новых терминов. Наиболее общие из них - нанонаука и нанотехнология [1]. Нанонаука - это фундаментальная химия, физика или биология, занимающиеся созданием и/или исследованием наноструктур. Нанотехнология — область прикладной науки и техники, занимающаяся изучением свойств объектов и разработкой устройств с размерами порядка нанометров.

Оптимизация структурной организации (морфологии) различных наноразмерных материалов - важная проблема, без решения которой невозможно улучшить их свойства и определить наиболее перспективные области их использования. Применение полимеров (в том числе и биополимеров) в качестве стабилизаторов наночастиц имеет продолжительную историю [2-4]. Варьируя свойства полимеров (наличие различных функциональных групп, молекулярную массу, гидрофильность или гидрофобность и т.д.) можно влиять на свойства получаемых материалов.

Под наноструктурами в полимерах мы понимаем регулярные микрогетерогенности (т.е. участки полимерного материала, обладающие межфазной поверхностью) нанометровых размеров. Использование наноструктурированных матриц для формирования наночастиц дает дополнительные преимущества. Наноструктуры в полимерных системах играют роль нанореакторов по отношению к растущим наночастицам: размер, распределение по размерам и форма наночастиц определяются параметрами наноструктур и условиями синтеза. Примерами таких наноструктурированных систем являются мицеллы блок-сополимеров, тонкие полимерные слои, нанопористые полимерные сетки и т.д.

Изменяя морфологию нанокомпозитов можно получать материалы с заданными свойствами. Так, например, для каталитических приложений наиболее перспективной является морфология множества мелких частиц (для увеличения площади поверхности) в хорошо проницаемой матрице. Для оптимизации магнитных свойств наночастиц необходимы тонкий контроль за распределением частиц по размерам и совершенство их кристаллической структуры.

Целью настоящей диссертации является разработка новых металлополимерных нанокомпозитов с различной морфологией, которая является наилучшей с точки зрения оптимизации свойств конечных материалов. Изучение процессов формирования металлополимерных композитов в виде частиц или слоев позволяет установить основные закономерности и выявить влияние состава и структуры на свойства полученных материалов.

2. Литературный обзор

Наноструктурированные материалы, содержащие металл в виде комплексов или наночастиц представляют интересную область нанонауки и нанотехнологии, поскольку внедрение металлов, их оксидов или комплексов позволяет придавать уникальные свойства полимерным материалам: каталитические, оптические, магнитные, и т.д. Присутствие металлокомплексов в полимерных системах, может способствовать формированию наноструктур. В свою очередь, присутствие наноструктур в полимерных системах позволяет осуществлять тонкий контроль над ростом наночастиц, их распределением по размерам, и структурой поверхности частиц. Вышеупомянутые характеристики наиболее важны в определении свойств наноматериалов и их возможных применений. Узкое распределение наночастиц по размерам является критическим фактором в развитии высокоорганизованных материалов для многих применений, поскольку оптические, магнитные и каталитические свойства сильно зависят от размера частиц. Эта специфическая область науки начала развиваться приблизительно 15 лет назад, когда впервые появились статьи о формировании наночастиц в микросегрегированных блок-сополимерах и блок-сополимерных мицеллах [5]. В настоящее время в этой области наблюдается стремительный рост числа публикаций и быстрый прогресс в открытии новых материалов [6].

5. Выводы

1. Впервые были синтезированы стабильные при комнатной температуре мономакромолекулярные структуры с морфологией ядро-оболочка на основе термочувствительного полимера - поли(Ы-винилкапролактама) за счет комплексообразования с ионами кобальта. Показано, что для формирования монодисперсных мономакромолекулярных наноструктур в процессе комплексообразования в водном растворе необходимо присутствие устойчивых глобулярных агрегатов и координационное число иона металла должно быть достаточным для обеспечения сшивки звеньев по ли(Т\1-винил капролактама).

2. Впервые синтезированы магнитные вирусоподобные частицы с триангуляционным числом более трех на основе монодисперсных частиц оксида железа. Показано, что фосфолипиды с блоками полиэтиленоксида и концевыми карбоксильными группами можно использовать для создания оболочки биосовместимых темплатов, способных инициировать самосборку протеиновой оболочки вирусов и образование вирусоподобных частиц.

3. Показана зависимость эффективности инкорпорирования наночастиц, функционализированных фосфолипидом, от их размера и установлено, что размерные эффекты являются результатом различной плотности и заряда фосфолипидной оболочки для наночастиц различных диаметров.

4. Показано, что вирусоподобные частицы являются суперпарамагнитными, что представляет большой интерес в дальнейшем их исследовании как агентов для повышения контраста в специфической магниторезонансной томографии.

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5. Изучено формирование нанокомпозита, состоящего из полиэлектролитных слоев на окиси алюминия. Показано, что нанесение первым слоем анионного полиэлектролита -полистиролсульфоната натрия позволяет значительно улучшить стабильность катионного хитозанового слоя.

6. Синтезированы наночастицы Pd в ультратонком слое хитозана, нанесенном на неорганический носитель, обработанный полистиролсуль фон атом натрия. Показано, что такие матрицы способны контролировать зарождение и рост наночастиц.

7. Изучено влияние условий формирования нанокомпозитов на их каталитические свойства. Показано, что полученные палладиевые катализаторы проявляют высокую каталитическую активность и селективность в реакции гидрирования дегидролиналоола. Стабильность катализаторов, простота получения и относительная дешевизна являются неоспоримыми преимуществами новых систем.

1. Г. Б. Сергеев, Нанохимия.//Университет, Москва, 2006; 333.

2. G. p. Schmid, Clusters and Colloids: From Theory to Applications.// VCH: Weinheim, Germany, 1994; 555.

3. J. H. Fendler, Nanoparticles and Nanostructured Films: Preparation, Characterization and Applications.// Wiley-VCH: New-York, 1998.

4. R. M. Crooks, et al. Dendrimer-encapsulated metals and semiconductors: Synthesis, characterization, and applications.// Topics Curr. Chem. 2001. V. 212.P. 81.

5. S. Forster, M. Antonietti. Amphiphilic Block Copolymers in Structure-Controlled Nanomaterial Hybrids.// Adv. Mater. 1998. V. 10.P. 195.

6. Functional Nanostructures.// Chemical Reviews. 2005. V. 105. № 4.

7. I. U. Hamley, The Physics of Block Copolymers.//Oxford University Press, Oxford, UK, 1998.

8. F. S. Bates, G. H. Fredrickson. Phys. Today. 1999. V. 52.P. 32.

9. L. M. Bronstein, P. M. Valetsky. Specific features of complexation of organometallic compounds with polybutadiene and its copolymer in solution // J. Inorg. Organomet. Polym. 1994. V. 4.P. 415.

10. M. Moffitt, et al. Size Control of Nanoparticles in Semiconductor-Polymer Composites. 2. Control via Sizes of Spherical Ionic Microdomains in Styrene-Based Diblock Ionomers.// Chem. Mater. 1995. V. 7. № 6. P. 1185.

11. L. Bronstein, et al. Transition metal complex induced morphology change in an ABC-triblock copolymer.// Polym. Bull. 1997. V. 39.P. 361.

12. J. F. Ciebien, et al. Brief review of metal nanoclusters in block copolymer films.//New J. Chem. 1998. V. 22.P. 685.

13. Т. Hashimoto, et al. Incorporation of Metal Nanoparticles into Block Copolymer Nanodomains via in-Situ Reduction of Metal Ions in Microdomain Space.//Macromolecules. 1999. V. 32.P. 6867.

14. Y. Lvov, et al. Assembly, structural characterization, and thermal behavior of layer-by-layer deposited ultrathin films of poly(vinyl sulfate) and poly(allylamine).// Langmuir. 1993. V. 9.P. 481.

15. G. В. Sukhorukov, et al. Layer-by-layer self assembly of polyelectrolytes on colloidal particles.// Colloids Surf., A. 1998. V. 137.P. 253.

16. R. A. Caruso, et al. Multilayered Titania, Silica, and Laponite Nanoparticle Coatings on Polystyrene Colloidal Templates and Resulting Inorganic Hollow Spheres // Chem. Mater. 2001. V. 13. № 2. P. 400.

17. H. Xiong, et al. Supramol. Sci. 1998. V. 5.P. 623.

18. N. A. Kotov, et al. Layer-by-Layer Self-Assembly of Polyelectrolyte-Semiconductor Nanoparticle Composite Films.// J. Phys. Chem. 1995. V. 99.P. 13065.

19. A. R. Khokhlov, et al. Conformational transitions in polymer gels: Theory and experiment // Adv.Polym.Sci. 1993. V. 109.P. 123.

20. A. R. Khokhlov, et al. Macromol. Theory Simul. 1992. V. l.P. 105.

21. Y. V. Khandurina, et al. Vysokomol. Soedin., Ser. A Ser. B. 1994. V. 36.P. 235.

22. H. Okuzaki, Y. Osada. Ordered-Aggregate Formation by Surfactant-Charged Gel Interaction.// Macromolecules. 1995. V. 28.P. 380.

23. F. Yeh, et al. Nanoscale Supramolecular Structures in the Gels of Poly(Diallyldimethylammonium Chloride) Interacting with Sodium Dodecyl Sulfate//J. Am. Chem. Soc. 1996. V. 118. №28. P. 6615.

24. L. M. Bronstein, et al. Complexes of Polyelectrolyte Gels with Oppositely Charged Surfactants: Interaction with Metal Ions and Metal Nanoparticle Formation.//Langmuir. 1998. V. 14.P. 252.

25. L. M. Bronstein, et al. Metal colloid formation in the complexes of polyelectrolyte gels with oppositely charged surfactants.// Colloids Surf A. 1999. V. 147. № 1-2. P. 221.

26. D. I. Svergun, et al. Small-Angle X-ray Scattering Study of Platinum-Containing Hydrogel/Surfactant Complexes // J. Phys. Chem. B. 2000. V. 104.P. 5242.

27. J. C. Hulteen, C. R. Martin, Template Synthesis of Nanoparticles in Nanoporous Membranes. In Nanoparticles and Nanostructured Films,// J. H. Fendler, Wiley-VCH Verlag: Weinheim, 1998; P. 235.

28. Y. Plyuto, et al. Ag nanoparticles synthesised in template-structured mesoporous silica films on a glass substrate.// Chem. Commun. 1999. P. 1653.

29. L. M. Bronstein, et al. Sub-Nanometer Noble-Metal Particle Host Synthesis in Porous Silica Monoliths.//Adv. Mater. 2001. V. 13.P. 1333.

30. V. A. Davankov, M. P. Tsyurupa. Structure and properties of hypercrosslinked polystyrene—the first representative of a new class of polymer networks.//React. Polym. 1990. V. 13.P. 27.

31. M. P. Tsyurupa, V. A. Davankov. The study of macronet isoporous styrene polymers by gel permeation chromatography // J. Polym. Sci.: Polym. Chem. Ed. 1980. V. 18.P. 1399.

32. R. M. C. Sutton, et al. High-performance chelation ion chromatography for the determination of traces of bismuth in lead by means of a novel hypercrosslinked polystyrene resin.// Journal of Chromatography, A. 1997. V. 789.P. 389.

33. S. N. Sidorov, et al. Cobalt Nanoparticle Formation in the Pores of Hyper-Cross-Linked Polystyrene: Control of Nanoparticle Growth and Morphology //Chem. Mater. 1999. V. 11. № 11. P. 3210.

34. S. V. Vonsovskii, Magnetism.//Nauka, Moscow, 1971.

35. C. P. Bean, et al. Determination of precipitate particle shape by ferromagnetic resonance.// ActaMetall. 1957. V. 5.P. 682.

36. S. N. Sidorov, et al. Platinum-Containing Hyper-Cross-Linked Polystyrene as a Modifier-Free Selective Catalyst for L-Sorbose Oxidation // J. Am. Chem. Soc. 2001. V. 123. № 43. P. 10502.

37. A. N. Parikh, et al. n-Alkylsiloxanes: From Single Monolayers to Layered Crystals. The Formation of Crystalline Polymers from the Hydrolysis of n-Octadecyltrichlorosilane // J. Am. Chem. Soc. 1997. V. 119. № 13. p. 3135.

38. W. R. Thompson, J. E. Pemberton. Characterization of Octadecylsilane and Stearic Acid Layers on A1203 Surfaces by Raman Spectroscopy.// Langmuir. 1995. V. 11.P. 1720.

39. L. M. Bronstein, et al. Metal Nanoparticles Grown in the Nanostructured Matrix of Poly(octadecylsiloxane).//Langmuir. 2000. V. 16.P. 8221.

40. D. I. Svergun, et al. Formation of Metal Nanoparticles in Multilayered Poly(octadecylsiloxane) As Revealed by Anomalous Small-Angle X-ray Scattering // Chem. Mater. 2000. V. 12. № 12. P. 3552.

41. Z. Lu, et al. Palladium Nanoparticle Catalyst Prepared in Poly (Acrylic Acid)-lined Channels of Diblock Copolymer Microspheres.// Nano Lett. 2001. V. l.P. 683.

42. M Antonietti, et al. Synthesis and characterization of noble metal colloids in block copolymer micelles.//Adv. Mater. 1995. V. 7.P. 1000.

43. L. M. Bronstein, et al. Controlled Synthesis of Novel Metallated Poly(aminohexyl)-(aminopropyl)silsesquioxane Colloids.// Langmuir. 2003. V. 19.P. 7071.

44. M. Mikhaylova, et al. Superparamagnetism of Magnetite Nanoparticles: Dependence on Surface Modification.// Langmuir. 2004. V. 20.P. 2472.

45. B. Lindlar, et al. Synthesis of monodisperse magnetic methacrylate polymer particles.//Adv. Mater. 2002. V. 14.P. 1656.

46. J. Zhang, et al. A New Approach to Hybrid Nanocomposite Materials with Periodic Structures.// J. Am. Chem. Soc. 2002. V. 124.P. 14512.

47. H. H. Pham, E. Kumacheva. Core-shell particles: Building blocks for advanced polymer materials.//Macromol. Symp. 2003. V. 192.P. 191.

48. I. L. Radtchenko, et al. Inorganic Particle Synthesis in Confined Micron-Sized Polyelectrolyte Capsules.// Langmuir. 2002. V. 18.P. 8204.

49. G. Kickelbick, et al. Hybrid Inorganic-Organic Core-Shell Nanoparticles from Surface-Functionalized Titanium, Zirconium, and Vanadium Oxo Clusters.// Chem. Mater. 2002. V. 14.P. 4382.

50. C. R. Vestal, Z. J. Zhang. Atom Transfer Radical Polymerization Synthesis and Magnetic Characterization of MnFe204/Polystyrene Core/Shell Nanoparticles.// J. Am. Chem. Soc. 2002. V. 124.P. 14312.

51. S. C. Farmer, Т. E. Patten. Photoluminescent Polymer/Quantum Dot Composite Nanoparticles.//Chem. Mater. 2001. V. 13.P. 3920.

52. J. Pyun, et al. Synthesis and characterization of organic/inorganic hybrid nanoparticles: kinetics of surface-initiated atom transfer radical polymerization and morphology of hybrid nanoparticle ultrathin films.// Macromolecules. 2003. V. 36.P. 5094.

53. Y. Deng, et al. A novel approach for preparation of thermoresponsive polymer magnetic microspheres with core-shell structure.// Adv. Mater. 2003. V. 15.P. 1729.

54. H. Skaff, T. Emrick. A Rapid Route to Amphiphilic Cadmium Selenide Nanoparticles Functionalized with Poly(ethylene glycol).// Chem. Comm. 2003. P. 52.

55. J. Jang, B. Lim. Facile Fabrication of Inorganic-Polymer Core-Shell Nanostructures by a One-Step Vapor Deposition Polymerization.// Angew. Chem. Int. Ed. 2003. V. 42.P. 5600.

56. J. Deng, et al. Magnetic and conducting Fe304-cross-linked polyaniline nanoparticles with core-shell structure.//Polymer. 2002. V. 43 .P. 2179.

57. J. L. Arias, et al. Synthesis and characterization of poly(ethyl-2-cyano aery late) nanoparticles with a magnetic core.// J. Controll. Release. 2001. V. 77.P. 309.

58. M. P. Morales, et al. Contrast agents for MR1 based on iron oxide nanoparticles prepared by laser pyrolysis.// J. Magn. Magn. Mater. 2003. V. 266.P. 102.

59. Y. Zhang, et al. Surface modification of superparamagnetic magnetite nanoparticles and their intracellular uptake.// Biomaterials. 2002. V. 23 .P. 1553.

60. M. Antonietti, S. Henz. Supermolecular structures at polymers. A way towards intelligent materials?// Nachr. Chem: Technol. Lab. 1992. V. 40.P. 308.

61. R. Saito, et al. Introduction of colloidal silver into poly(2-vinylpyridine) microdomains of microphage-separated poly(styrene-b-2-vinylpyridine) film. 3. Poly(2-vinylpyridine) spherical microdomain.// Polymer. 1993. V. 34.P. 1189.

62. J. P. Spatz, et al. Gold nanoparticles in micellar poly(styrene)-b-poly(ethylene oxide) films. Size and interparticle distance control in monoparticulate films.// Adv. Mater. 1996. V. 8.P. 337.

63. A. B. R. Mayer, et al. Palladium and platinum nanocatalysts protected by amphiphilic block copolymers.// Polym. J. 1998. V. 30.P. 197.

64. A. B. R. Mayer, J. E. Mark. Transition metal nanoparticles protected by amphiphilic block copolymers as tailored catalyst systems.// Colloid Polym. Sci. 1997. V. 275.P. 333.

65. L. M. Bronstein, et al. Interaction of Polystyrene-block-poly(ethylene oxide) Micelles with Cationic Surfactant in Aqueous Solutions. Metal Colloid Formation in Hybrid Systems.// Langmuir. 2000. V. 16.P. 3626.

66. L. M. Bronstein, et al. The Hybrids of Polystyrene-block-Poly(ethylene Oxide) Micelles and Sodium Dodecyl Sulfate in Aqueous Solutions: Interaction with Rh Ions and Rh Nanoparticle Formation.// J. Colloid Interface Sci. 2000. V. 230.P. 140.

67. L. M. Bronstein, et al. Comicellization of Polystyrene-block-Poly(ethylene oxide) with Cationic and Anionic Surfactants in Aqueous Solutions: Indications and Limits.// J. Phys. Chem. B. 2001. Y. 105.P. 9077.

68. L. M. Bronstein, et al. Synthesis of Pd-, Pt-, and Rh-containing polymers derived from polystyrene-polybutadiene block copolymers; micellization of diblock copolymers due to complexation.// Macromol. Chem. Phys. 1998. V. 199.P. 1357.

69. L. M. Bronstein, et al. Interaction of metal compounds with 'double-hydrophilic' block copolymers in aqueous medium and metal colloid formation.// Inorg. Chim. Acta. 1998. V. 280.P. 348.

70. S. N. Sidorov, et al. Stabilization of Metal Nanoparticles in Aqueous Medium by Polyethyleneoxide-Polyethyleneimine Block Copolymers.// J. Colloid Interface Sci. 1999. V. 212.P. 197.

71. M. Michaelis, A. Henglein. Reduction of Pd(Il) in Aqueous Solution: Stabilization and Reactions of an Intermediate Cluster and Pd Colloid Formation.// J. Phys. Chem. 1992. V. 96.P. 4719.

72. M. Antonietti. Microgels Polymers with a Special Molecular Architecture.// Angew. Chem. Int. Ed. 1988. V. 27.P. 1743.

73. M. Antonietti, et al. Microgels: model polymers for the crosslinked state.// Macromolecules. 1990. V. 23.P. 3796.

74. M. Antonietti, et al. Nonclassical Shapes of Noble-Metal Colloids by Synthesis in Microgel Nanoreactors.// Angew. Chem. Int. Ed. 1997. V. 36.P. 2080.

75. N. T. Whilton, et al. Organized functionalization of mesoporous silica supports using prefabricated metal-polymer modules.// Adv. Mater. 1999. V. 11.P. 1014.

76. F. Zeng, S. C. Zimmerman. Dendrimers in Supramolecular Chemistry: From Molecular Recognition to Self-Assembly // Chem. Rev. 1997. V. 97. № 5. P. 1681.

77. M. Zhao, R. M. Crooks. Dendrimer-Encapsulated Pt Nanoparticles: Synthesis, Characterization, and Applications to Catalysis.// Adv. Mater. 1999. V. 11.P. 217.

78. К. Esumi, et al. Preparation of Gold Colloids with UV Irradiation Using Dendrimers as Stabilizer.//Langmuir. 1998. V. 14.P. 3157.

79. K. Esumi, et al. Preparation of Gold Colloids with UV Irradiation Using Dendrimers as Stabilizer.//Langmuir. 1998. V. 14.P. 3157.

80. M. Benito, et al. Transition metal clusters containing carbosilane dendrimers.// J. Organomet. Chem. 2001. V. 619.P. 245.

81. M. Benito, et al. Very large neutral and polyanionic Fe/Au cluster-containing dendrimers.// J. Organomet. Chem. 2001. V. 622.P. 33.

82. O. Ross ell, et al. Gold-containing dendrimers: A new class of macromolecules.// Gold Bulletin. 2001. V. 34.P. 88.

83. Z. B. Shifrina, et al. Poly(Phenylene-pyridyl) Dendrimers: Synthesis and Templating of Metal Nanoparticles.// Macromolecules. 2005. V. 38. № 24. P. 9920.

84. A. Wieckowski, et al., Catalysis and Electrocatalysis at Nanoparticle Surfaces.//Marcel Dekker, Inc., New York, N. Y., 2003; 970.

85. G. Schmid, Nanoparticles: From Theory to Application.// Wiley-VCH Verlag GmbH & Co.: Weinheim, 2004; 434.

86. G. A. Somorjai, et al. Clusters, surfaces, and catalysis.// Proc. Nat. Acad. Sci. 2006. V. 103. № 28. P. 10577.

87. D. Astruc, et al. Nanoparticles as recyclable catalysts. The frontier between homogeneous and heterogeneous catalysis.// Angew. Chem. Int. Ed. 2005. V. 44.P. 7852.

88. C. Mueller, et al. Continuous homogeneous catalysis.// European Journal of Inorganic Chemistry. 2005. V. 20.P. 4011.

89. L. M. Bronstein, Nanoparticles in Nanostructured Polymers. In Encyclopedia of Nanoscience and Nanotechnology,// H. S. Nalwa, APS: Stevenson Ranch, CA, 2004; V. 7, P. 193.

90. L. M. Bronstein, Polymer Colloids and Their Metallation. In Dekker Encyclopedia of Nanoscience and Nanotechnology,// J. A. Schwarz, С. I. Contescu and K. Putyera, Marcel Dekker, Inc.: New York, 2004; P. 2903.

91. S. Klingelhoefer, et al. Preparation of Palladium Colloids in Block Copolymer Micelles and Their Use for the Catalysis of the Heck Reaction // J. Am. Chem. Soc. 1997. V. 119. №42. P. 10116.

92. M. V. Seregina, et al. Preparation of Noble-Metal Colloids in Block Copolymer Micelles and Their Catalytic Properties in Hydrogenation.// Chem. Mater. 1997. V. 9.P. 923.

93. R. S. Underbill, G. Liu. Triblock Nanospheres and Their Use as Templates for Inorganic Nanoparticle Preparation.// Chem. Mater. 2000. V. 12.P. 2082.

94. R. S. Mulukutla, et al Nanoparticles of RhOx in the MCM-41: a novel catalyst for NO-CO reaction in excess 02.// Scripta. Mater. 2001. V. 44.P. 1695.

95. T. F. Jaramillo, et al. Catalytic Activity of Supported Au Nanoparticles Deposited from Block Copolymer Micelles.// J. Am. Chem. Soc. 2003. V. 125. №24. P. 7148.

96. B. Roldan Cuenya, et al. Size- and Support-Dependent Electronic and Catalytic Properties of Au0/Au3+ Nanoparticles Synthesized from Block Copolymer Micelles.// J. Am. Chem. Soc. 2003. V. 125. № 42. P. 12928.

97. R. Nakao, et al. Hydrogenation and Dehalogenation under Aqueous Conditions with an Amphiphilic-Polymer-Supported Nanopalladium Catalyst.// Organic Letters. 2005. V. 7. № 1. P. 163.

98. L. Groeschel, et al. Hydrogenation of Propyne in Palladium-Containing Polyacrylic Acid Membranes and Its Characterization.// Industrial & Engineering Chemistry Research. 2005. V. 44. № 24. P. 9064.

99. L. Groeschel, et al. Characterization of Palladium Nanoparticles Adsorbed on Polyacrylic Acid Particles as Hydrogenation Catalyst.// Catalysis Letters.2004. V. 95. № 1-2. P. 67.

100. Z. Liu, et al. Silver nanocomposite layer-by-layer films based on assembled polyelectrolyte/dendrimer.// J. Colloid Interface Sci. 2005. V. 287. № 2. P. 604.

101. Y Li, M. A. El-Sayed. The Effect of Stabilizers on the Catalytic Activity and Stability of Pd Colloidal Nanoparticles in the Suzuki Reactions in Aqueous Solution.//J. Phys. Chem., B. 2001. V. 105.P. 8938.

102. R. Narayanan, M. A. El-Sayed. Effect of Colloidal Catalysis on the Nanoparticle Size Distribution: Dendrimer-Pd vs PVP-Pd Nanoparticles Catalyzing the Suzuki Coupling Reaction.// J. Phys. Chem. 2004. V. 108. № 25. P. 8572.

103. J. Lemo, et al. Efficient Dendritic Diphosphino Pd(II) Catalysts for the Suzuki Reaction of Chloroarenes.// Organic Letters. 2005. V. 7. № 11. P. 2253.

104. M. Zhao, R. M. Crooks. Intradendrimer Exchange of Metal Nanoparticles // Chem. Mater. 1999. V. 11. № 11. P. 3379.

105. Y. Niu, et al. Size-Selective Hydrogenation of Olefins by Dendrimer-Encapsulated Palladium Nanoparticles.// J. Am. Chem. Soc. 2001. V. 123. № 28. P. 6840.

106. S.-K. Oh, et al. Size-Selective Catalytic Activity of Pd Nanoparticles Encapsulated within End-Group Functionalized Dendrimers.// Langmuir.2005. V. 21. №22. P. 10209.

107. О. M. Wilson, et al. Effect of Pd Nanoparticle Size on the Catalytic Hydrogenation of Allyl Alcohol.// J. Am. Chem. Soc. 2006. V. 128. № 14. P. 4510.

108. К. Esumi, et al. Preparation and catalytic activity of platinum-dendrimer nanocomposites.// Shikizai Kyokaishi. 2000. V. 73. № 9. P. 434.

109. J. C. Garcia-Martinez, et al. Dendrimer-Encapsulated Pd Nanoparticles as Aqueous, Room-Temperature Catalysts for the Stille Reaction.// J. Am. Chem. Soc. 2005. V. 127. № 14. P. 5097.

110. T. Endo, et al. Synthesis and catalytic activity of gold-silver binary nanoparticles stabilized by РАМАМ dendrimer.// J. Colloid Interface Sci. 2005. V. 286. №2. P. 602.

111. Y. Du, et al. Preparation of Platinum Core-polyaryl Ether Aminediacetic Acid Dendrimer Shell Nanocomposite for Catalytic Hydrogenation of Phenyl Aldehydes.// Catalysis Letters. 2006. V. 107. №> 3-4. P. 177.

112. J. Dai, M. L. Bruening. Catalytic Nanoparticles Formed by Reduction of Metal Ions in Multilayered Polyelectrolyte Films.// Nano Lett. 2002. V. 2.P. 497.

113. M. I. Baraton, Synthesis, functionalisation and surface treatment of nanoparticles.//Am. Sci. Publ., Los-Angeles, CA, 2002.

114. E. Кондорский. Докл. АН СССР. 1952. V. 82.Р. 365.

115. С. Kittel. Theory of the Structure of Ferromagnetic Domains in Films and Small Particles // Phys. Rev. 1946. V. 70.P. 965.

116. W. F. Brown Jr. Thermal Fluctuations of a Single-Domain Particle.// J. Appl. Phys. 1963. V. 34.P. 1319.

117. W. C. Elmor. Ferromagnetic Colloid for Studying Magnetic Structures.// Phys. Rev. 1938. V. 54.P. 309.

118. C. P. Bean, I. S. Jacobs. Magnetic Granulometry and Super-Paramagnetism // J. Appl. Phys. 1955. V. 27.P. 1448.

119. E. F. Kneller, F. E. Luborsky. Particle Size Dependence of Coercivity and Remanence of Single-Domain Particles.// J. Appl. Phys. 1963. V. 34.P. 656.

120. J. R. Thomas. Preparation and Magnetic Properties of Colloidal Cobalt Particles.//J. Appl. Phys. 1966. V. 37.P. 2914.

121. G. A. Prinz. Magnetoelectronics applications.// J. Magn. Magn. Mater. 1999. V. 200.P. 57.

122. D. Das, et al. Synthesis of nanocrystalline nickel oxide by controlled oxidation of nickel nanoparticles and their humidity sensing properties.// J. Appl. Phys. 2000. V. 88.P. 6856.

123. W. J. Parak, et al. Biological applications of colloidal nanocrystals.// Nanotechnology. 2003. V. 14.P. R15.

124. O. A. Platonova, et al. Cobalt nanoparticles in block copolymer micelles: Preparation and properties.// Colloid Polym. Sci. 1997. V. 275. № 5. P. 426.

125. M. Rutnakornpituk, et al. Formation of cobalt nanoparticle dispersions in the presence of polysiloxane block copolymers.// Polymer. 2002. V. 43 .P. 2337.

126. P. A. Dresco, et al. Preparation and Properties of Magnetite and Polymer Magnetite Nanoparticles.//Langmuir. 1999. V. 15.P. 1945.

127. V. S. Zaitsev, et al. Physical and Chemical Properties of Magnetite and Magnetite-Polymer Nanoparticles and Their Colloidal Dispersions.// J. Colloid Interface Sci. 1999. V. 212.P. 49.

128. T. A. Taton. Nanostructures as tailored biological probes // Trends Biotechnol. 2002. V. 20.P. 277.

129. C. Mah, et al. Microsphere-mediated delivery of recombinant AAV vectors in vitro and in vivo.// Mol Therapy. 2000. V. 1 .P. S239.

130. D. Panatarotto, et al. Immunization with peptide-functionalized carbon nanotubes enhances virus-specific neutralizing antibody responses.// Chemistry&Biology. 2003. V. 10.P. 961.

131. R. L. Edelstein, et al. The BARC biosensor applied to the detection of biological warfare agents.// Biosensors Bioelectron. 2000. V. 14.P. 805.

132. J. M. Nam, et al. Nanoparticles-based bio-bar codes for the ultrasensitive detection of proteins.// Science. 2003. V. 301.P. 1884.

133. R. Mahtab, et al. Protein-sized quantum dot luminescence can distinguish between "straight", "bent", and "kinked" oligonucleotides.// J. Am. Chem. Soc. 1995. V. 117.P. 9099.

134. J. Ma, et al. Biomimetic processing of nanocrystallite bioactive apatite coating on titanium.//Nanotechnology. 2003. V. 14.P. 619.

135. A. de la Isla, et al. Nanohybrid scratch resistant coating for teeth and bone viscoelasticity manifested in tribology.// Mat. Resr. Innovat. 2003. V. 7.P. 110.

136. J. Yoshida, T. Kobayashi. Intracellular hyperthermia for cancer using magnetite cationic liposomes.//J. Magn. Magn. Mater. 1999. V. 194.P. 176.

137. R. S. Molday, D. MacKenzie. Immunospecific ferromagnetic iron dextran reagents for the labeling and magnetic separation of cells.// J. Immunol. Methods. 1982. V. 52.P. 353.

138. M. Bruchez, et al. Semiconductor nanocrystals as fluorescent biological labels.// Science. 1998. V. 281.P. 2013.

139. W. C. W. Chan, S. M. Nie. Quantum dot bioconjugates for ultrasensitive nonisotopic detection.// Science. 1998. V. 281.P. 2016.

140. S. Wang, et al. Antigen/antibody immunocomplex from CdTe nanoparticle bioconjugates.//Nano Letters. 2002. V. 2.P. 817.

141. R. Weissleder, et al. Ultrasmall superparamagnetic iron oxide: characterization of a new class of contrast agents for MR imaging.// Radiology. 1990. V. 175.P. 489.

142. V. A. Sinani, et al. Collagen coating promotes biocompatibility of semiconductor nanoparticles in stratified LBL films.// Nano Letters. 2003. V. 3.P. 1177.

143. M. Han, et al Quantum-dot-tagged microbeads for multiplexed optical coding of biomolecules.//Nature Biotechnology. 2001. V. 19.P. 631.

144. I. Roy, et al. Ceramic-based nanoparticles entrapping water-insoluble photosensitizing anticancer drugs: a novel drug-carrier system for photodynamic therapy.// J. Am. Chem. Soc. 2003. V. 125.P. 7860.

145. J. L. West, N. J. Halas. Applications of nanotechnology to biotechnology.// Curr. Opin. Biotechnol. 2000. V. 11.P. 215.

146. S. R. Sershen, et al. Temperature-sensitive polymer-nanoshell composite for photothermally modulated drug delivery.// J. Biomed. Mater. Res. 2000. V. 51.P. 293.

147. Q. A. Pankhurst, et al. Applications of magnetic nanoparticles in biomedicine.// J. Phys. D: Appl. Phys. 2003. V. 36.P. R167.

148. D. H. Reich, et al. Biological applications of multifunctional magnetic nanowires.// J. Appl. Phys. 2003. V. 93.P. 7275.

149. С. H. Cunningham, et al. Positive contrast magnetic resonance imaging of cells labeled with magnetic nanoparticles.// Magn. Reson. Med. 2005. V. 53.P. 999.

150. M. Johannsen, et al. Clinical hyperthermia of prostate cancer using magnetic nanoparticles: Presentation of a new interstitial technique.// Int. J. Hyperthermia. 2005. V. 21. № 7. P. 637.

151. R. Jurgons, et al. Drug loaded magnetic nanoparticles for cancer therapy.// J. Phys.: Condens. Matter. 2006. V. 18. № 38. P. S2893.

152. B. Dubertret, et al. In vivo imaging of quantum dots encapsulated in phospholipid micelles.// Science. 2002. V. 298. № 5599. P. 1759.

153. C. Chen, et al. Nanoparticle-Templated Assembly of Viral Protein Cages.// Nano Lett. 2006. V. 6. № 4. P. 611.

154. S. К. Dixit, et al. Quantum Dot Encapsulation in Viral Capsids.// Nano Lett. 2006. V. 6. № 9. P. 1993.

155. V. Holler, et al. Reduction of nitrite-ions in water over Pd-supported on structured fibrous materials.//Appl. Catal. 2001. V. B32.P. 143.

156. A. A. Askadskii, Computational Materials Science of Polymers.//Cambridge International Science Publishing, Cambridge, 2003.

157. R. L. Kronenthal, et al. Polymer Science and Technology: Polymers in Medicine and Surgery.// Plenum Press: New York and London, . 1975. V. Vol. 8.

158. W. S. Shalaby, a. et. Polymers of Biological and Biomedical Significance./7 American Chemical Society: Washington, DC. 1994.

159. L. M. Mikheeva, et al. Microcalorimetric Study of Thermal Cooperative Transitions in Poly(N-vinylcaprolactam) Hydrogels.// Macromolecules. 1997. V. 30. №9. P. 2693.

160. B. Jeong, et al. Biodegradable block copolymers as injectable drug-delivery systems.// Nature. 1997. V. 388(6645).P. 860.

161. R. M. Ottenbrite, et al. Hydrogels and Biodegradable Polymers for Bioapplications.// American Chemical Society: Washington, DC. 1996.

162. K. Park. Controlled Drug Delivery-Challenges and Strategies // Amercian Chemical Society: Washington, DC. 1997.

163. A. S. Hoffman. Applications of thermally reversible polymers and hydrogels in therapeutics and diagnostics // J. Controlled Release 1987. V. 6 P. 297.

164. A. S. Hoffman, et al. Thermally reversible hydrogels: II. Delivery and selective removal of substances from aqueous solutions // J. Controlled Release. 1986. V. 4.P. 213.

165. H. Feil, et al Molecular separation by thermosensitive hydrogel membranes // J. Membr. Sci. 1991. V. 64.P. 283.

166. Y. R.-M. Osada, S. B. . Intelligent Gels.// Sci. Am. 1993. V. 259.P. 42.

167. S. Luo, e. al. Phase Transition Behavior of Unimolecular Micelles with Thermoresponsive Poly(N-isopropylacrylamide) Coronas.// J. Phys. Chem. B. 2006. P. 9132.

168. A. Mehta, et al. Oriented Nanostructures from Single Molecules of a Semiconducting Polymer: Polarization Evidence for Highly Aligned Intramolecular Geometries.// Nano Lett. 2003. V. 3.P. 603.

169. P. Kumar, et al. Photon Antibunching from Oriented Semiconducting Polymer Nanostructures.// J. Am. Chem. Soc. 2004. V. 126.P. 3376.

170. M. Zhang, et al. Template-Controlled Synthesis of Wire-Like Cadmium Sulfide Nanoparticle Assemblies within Core-Shell Cylindrical Polymer Brushes.// Chem. Mater. 2004. V. 16.P. 537.

171. E. E. Makhaeva, et al. Thermoshrinking behavior of poly(vinyleaprolactam) gels in aqueous solution//Macromol. Chem. Phys. 1996. V. 197.P. 1973.

172. L. M. Bronstein, et al. Core-Shell Nanostructures from Single Poly(N-vinylcaprolactam) Macromolecules: Stabilization and Visualization.// Langmuir. 2005. V. 21. № 7. P. 2652.

173. V. Lebedev, et al. Polymer hydration and microphase decomposition in poly(N-vinylcaprolactam)-water complex.// J. Appl. Crystallogr. 2003. V. 36.P. 967.

174. V. V. Vasilevskaya, et al. Conformational Polymorphism of Amphiphilic Polymers in a Poor Solvent.// Macromolecules. 2003. V. 36.P. 10103.

175. F. Zeng, et al. NMR investigation of phase separation in poly(N-isopropylacrylamide)/water solutions.//Polymer. 1997. V. 38.P. 5539.

176. A. Larsson, et al. 1H NMR of thermoreversible polymers in solution and at interfaces: the influence of charged groups on the phase transition.// Coll. & Surfaces A. 2001. V. 190.P. 185.

177. К. Yokota, et al. A carbon-13 nuclear magnetic resonance study of covalently crosslinked gels. Effect of chemical composition, degree of crosslinking, and temperature to chain mobility.// Macromolecules. 1978. V. ll.P. 95.

178. G. Zhang, et al. Structure of a Collapsed Polymer Chain with Stickers: A Single- or Multiflower?// Phys. Rev. Lett. 2003. V. 90.P. 035506/1.

179. G. Wilkinson, Comprehensive coordination chemistry : the synthesis, reactions, properties, & applications of coordination compounds.//Pergamon Press, New York, 1987.

180. G. I. Frolov. Film carriers for super-high-density magnetic storage // Tech.Phys. 2001. V. 46. № 12. P. 1537.

181. S. H. Sun, et al. Monodisperse FePt nanoparticles and ferromagnetic FePt nanocrystal superlattices.// Science. 2000. V. 287. № 5460. P. 1989.

182. C. Sestier, et al Surface modification of superparamagnetic nanoparticles (Ferrofluid) studied with particle electrophoresis: Application to the specific targeting of cells.//Electrophoresis. 1998. V. 19. № 7. P. 1220.

183. M Racuciu, et al Synthesis and. rheological properties of an aqueous ferrofluid.// J. Optoelectron. Adv. Mater. 2005. V. 7. № 6. P. 2859.

184. J. W. Bulte, D. L. Kraitchman. Iron oxide MR contrast agents for molecular and cellular imaging.//NMR Biomed. 2004. V. 17.P. 484.

185. W. J. M. Mulder, et al. Lipid-based nanoparticles for contrast-enhanced MRJ and molecular imaging.//NMR Biomed. 2006. V. 19. № 1. P. 142.

186. Y. R. Chemla, et al Ultrasensitive magnetic biosensor for homogeneous immunoassay //Proc. Nat. Acad. Sci. 2000. V. 97. № 26. P. 14268.

187. K. Briley-Saebo, et al. Hepatic cellular distribution and degradation of iron oxide nanoparticles following single intravenous injection in rats: implications for magnetic resonance imaging.// Cell & Tissue Res. 2004. V. 316. №3. P. 315.

188. Shen L.F., et al. Bilayer surfactant stabilized magnetic fluids: Synthesis and interactions at interfaces // Langmuir. 1999. V. 15. № 2. P. 447.

189. Fried Т., et al. Ordered two-dimensional arrays of ferrite nanoparticles // Adv. Mater. 2001. V. 13. №> 15. P. 1158.

190. G. Visalakshi, et al. Compositional characteristics of magnetite synthesized from aqueous-solutions at temperatures up to 523K.// Mater. Res. Bull. 1993. V. 28. № 8. P. 829.

191. Zhou ZH, et al. Synthesis of Fe304 nanoparticles from emulsions 11 Journal of materials chemistry 2001. V. 11. № 6. P. 1704.

192. Murray CB, et al. Synthesis and characterization of monodisperse nanocrystals and close-packed nanocrystal assemblies.// Annual review of materials science. 2000. V. 30.P. 545.

193. Tartaj P, Serna С J. Microemulsion-assisted synthesis of tunable superparamagnetic composites // Chemistry of materials 2002. V. 14. № 10. P. 4396.

194. S. Sun, H. Zeng. Size-Controlled Synthesis of Magnetite Nanoparticles.// J. Am. Chem. Soc. 2002. V. 124. № 28. P. 8204.

195. Z. Li, et al. One-Pot Reaction to Synthesize Water-Soluble Magnetite Nanocrystals.// Chem. Mater. 2004. V. 16. № 8. P. 1391.

196. F. X. Redl, et al. Magnetic, Electronic, and Structural Characterization of Nonstoichiometric Iron Oxides at the Nanoscale.// J. Am. Chem. Soc. 2004. V. 126. №44. P. 14583.

197. W. W. Yu, et al. Synthesis of monodisperse iron oxide nanocrystals by thermal decomposition of iron carboxylate salts.// Chem. Comm. 2004. № 20. P. 2306.

198. J. Park, et al. Ultra-large-scale syntheses of monodisperse nanocrystals.// Nature Mater. 2004. V. 3. № 12. P. 891.

199. Hyeon T, et al. Synthesis of Highly-Crystalline and Monodisperse Maghemite Nanocrystallites without a Size-Selection Process.// J. Am. Chem. Soc. 2001. V. 123. № 12798-12801.

200. T. Douglas, M. Young. Host-guest encapsulation of materials by assembled virus protein cages.// Nature. 1998. V. 393. № 6681. P. 152.

201. M. Allen, et al. Protein cage constrained synthesis of ferrimagnetic iron oxide nanoparticles.// Adv. Mater. 2002. V. 14. № 21. P. 1562.

202. D. V. Talapin, et al., Synthesis and Characterization of Magnetic Nanoparticles. In Nanoparticles,// G. Schmid, Wiley-VCH: Weinheim, 2004; P. 199.

203. T. Hyeon, et al. Synthesis of Highly Crystalline and Monodisperse Maghemite Nanocrystallites without a Size-Selection Process.// J. Am. Chem. Soc. 2001. V. 123.P. 12798.

204. D. Pouliquen, et al. Superparamagnetic iron oxide nanoparticles as a liver MRI contrast agent: contribution of microencapsulation to improved biodistribution.// Magn. Reson. Imag. . 1989. V. 7. № 6. P. 619.

205. E. M. Shapiro, et al. MRI detection of single particles for cellular imaging.// Proc. Nat. Acad. Sci. 2004. V. 101. № 30. P. 10901.

206. В. Dragnea, et al. Gold nanoparticles as spectroscopic enhancers for in vitro studies on single viruses.// J. Am. Chem. Soc. 2003. V. 125. № 21. P. 6374.

207. L. M. Bronstein, et al. Influence of Iron Oleate Complex Structure on Iron Oxide Nanoparticle Formation.// Chem. Mater, submitted. 2007. V. 19 №15. P. 3624.

208. L. M. Bronstein, et al. Influence of Iron Oleate Complex Structure on Iron Oxide Nanoparticle Formation.// Chem. Mater, submitted. 2006.

209. M. F. Casula, et al. The Concept of Delayed Nucleation in Nanocrystal Growth Demonstrated for the Case of Iron Oxide Nanodisks.// J. Am. Chem. Soc, 2006. V. 128. №5. P. 1675.

210. G. Ketteler, et al. Bulk and surface phases of iron oxides in an oxygen and water atmosphere at low pressure.// Phys. Chem. Chem. Phys. 2001. V. 3. № 6. P. 1114.

211. N. Nitin, et al. Functionalization and peptide-based delivery of magnetic nanoparticles as an intracellular MRI contrast agent.// J. Biol. Inorg. Chem. . 2004. V. 9. № 6. P. 706.

212. Y. T. Lim, et al. Immobilization of histidine-tagged proteins by magnetic nanoparticles encapsulated with nitrilotriacetic acid (NTA)-phospholipids micelle.//Biochem. Biophys.l Res. Comm. 2006. V. 344. № 3. P. 926.

213. J. Xie, et al. One-pot synthesis of monodisperse iron oxide nanoparticles for potential biomedical applications.// Pure Appl. Chem. 2006. V. 78. № 5. P. 1003.

214. X. Huang, et al. Self-Assembled Virus-like Particles with Magnetic Cores.// Nano Lett. 2007. V. 7. № 8. P. 2407.

215. R. W. Lucas, et al. The Crystallographic Structure ofBrome Mosaic Virus.// J. Molec. Biol. 2002. V. 317. № 1. P. 95.

216. К. W. Adolph, P. J. G. Butler. Reassembly of a spherical vims in mild conditions.//Nature. 1975. V. 255.P. 737.

217. Percec V. Self-assembly of viruses as models for the design of new macromolecular and supramolecular architectures.// Journal of macromolecular science. Part A. Pure & applied chemistry 1996. V. A33. № 10. P. 1479.

218. J. M. Kaper, The Chemical Basis of Virus Structure, Dissociation and Reassembly .//North-Holland, Amsterdam., 1975; 333.

219. J. В. Bancroft, et al. Structures derived from cowpea chlorotic mottle and brome mosaic virus protein. .// Virology. 1969. V. 38.P. 324.

220. R. W. Lucas, et al. Crystallization of brome mosaic virus and T=T brome mosaic virus particles following a structural transition.// Virology. 2001. V. 286. № 2. P. 290.

221. J. Sun, et al. Corecontrolled Polymorphism in Viruslike Particles.// Proc. Nat. Acad. Sci. 2006. V. 104.P. 1354.

222. R. W. Lucas, et al. The crystallographic structure of brome mosaic virus.// Journal of Molecular Biology. 2002. V. 317. № 1. P. 95.

223. W. D. Luedtke, U. Landman. Structure and thermodynamics of self-assembled monolayers on gold nanocrystallites.// Journal of Physical Chemistry B. 1998. V. 102. № 34. P. 6566.

224. U. Hartmann. Magnetic force microscopy.// Annual Review of Materials Science. 1999. V. 29.P. 53.

225. M. Rasa, et al. Atomic force microscopy and magnetic force microscopy study of model colloids.// Journal of Colloid and Interface Science. 2002. V. 250. №2. P. 303.

226. R. B. Proksch, et al. Magnetic Force Microscopy of the Submicron Magnetic Assembly in a Magnetotactic Bacterium.// Applied Physics Letters. 1995. V. 66. № 19. P. 2582.

227. I. Tsvetkova, et al. Nanostructured catalysts for the synthesis of vitamin intermediate products // Topics in Catalysis. 2006. V. 39. № 3-4.

228. L. Ruzicka, et al. Polyterpenes and poly terpenoids. CXXV. Rearrangement and cyclization of sclareol and dihydrosclareol.// Helv. Chim. Acta. 1938. V. 21.P. 364.

229. H. Mayer, et al Chemistry of vitamin E. IV. Absolute configuration of natural a-tocopherol.// Helv. Chim. Acta. 1963. V. 46.P. 963.

230. V. V. Rusak, et al Russ. J. Appl. Chem. 1994. V. 67.P. 1066.

231. F. Caruso, et al. Electrostatic Self-Assembly of Silica Nanoparticle-Polyelectrolyte Multilayers on Polystyrene Latex Particles // J.Am.Chem.Soc. 1998. V. 120. № 33. P. 8523.

232. F. Caruso, et al. Investigation of Electrostatic Interactions in Poly electrolyte Multilayer Films: Binding of Anionic Fluorescent Probes to Layers assembled onto Colloids.// Macromolecules. 1999. V. 32(7).P. 2317.

233. I. B. Tsvetkova, et al Structure and behavior of nanoparticulate catalysts based on ultrathin chitosan layers.// J. Mol. Catal. A: Chem. 2007. V. 276.P. 116.

234. R. Greenwood, K. Kendall. Effect of ionic strenght on the adsorption of cationic polyelectrolytes onto alumina studied using electroacoustic measurements.//Powder Technology. 2000. V. 113.P. 148.

235. J. R. Anderson, Structure of Metallic Catalysts.//Academic Press, London, 1975.

236. S. Kidambi, M. L. Bruening. Multilayered polyelectrolyte films containing palladium nanoparticles: synthesis, characterization, and application in selective hydrogenation.// Chem. Mater. 2005. V. 17.P. 301.

237. IUPAC, Recommendation. Reporting Physisorption Data for Gas/Solid Systemwith Special Reference to the Determination of Surface Area and Porosity.// Pure & Appl. Chem. 1985. V. 57. № 4. P. 603.

238. IUPAC, Recommendation 1994, 1739. Recommendations for the characterization of porous solids (Technical Report) Commission on Colloid and Surface Chemistry including Catalysis.// Pure & Appl. Chem. 1994. V. 66.P. 1739.

239. S. J. Gregg, K. S. W. Sing, Adsorption, Surface Area and Porosity.//Academic Press, London, 1982.

240. K. S. W. Sing. Reporting Physisorption Data for Gas/Solid System. Swith Special Reference to the Determination of Surface Area and Porosity. .// Pure & Appl.Chem. 1982. V. 54. № 11. P. 2201.

241. E. Brunet, et al. Solid-state reshaping of crystals: Flash increase in porosity of zirconium phosphate-hypophosphite that contains polyethylenoxa diphosphonate pillars.// Angew. Chem. Int. Ed. 2004. V. 43. № 5. P. 619.

242. K. Kaneko. Determination of pore size and pore size distribution. 1.Adsorbents and catalysts.//J. Memb. Sci. 1994. V. 96.P. 59.

243. K. Suzuki, et al. Control of the distance between the silicate layers of hectorite by pillaring with alumina in the presence of polyvinyl alcohol.// Chem. Comm. 1991. № 13. P. 873.

244. К. Suzuki, Т. Mori. Thermal and catalytic properties of alumina-pillared Montmorillonite prepared in the presence of polyvinyl alcohol.// Appl.Catal. 1990. V. 63.P. 181.

245. H. Y Zhu, G. Q. Lu. Engineering the Structures of Nanoporous Clays with Micelles of Alkyl Polyether Surfactants.// Langmuir. 2001. V. 17.P. 588.

246. Y. Lvov, etal. Langmuir. 1993. V. 9.P. 481.

247. G. B. Sukhorukov, etal. Colloids Surf., A. 1998. V. 137.P. 253.

248. R. A. Caruso, et al. Chem. Mater. 2001. V. 13.P. 400.

249. N. A. Kotov, ;, et al. J. Phys. Chem. 1995. V. 99.P. 13065.

250. A. M. Blokhus, K. Djurhuus. Adsorption of poly(styrene sulfonate) of different molecular weights on a-alumina. Effect of added sodium dodecyl sulfate.// J. Colloid Interface Sci. 2006. V. 296. № 1. P. 64.

251. K. Nadarajah, et al. Sorption behavior of crawfish chitosan films as affected by chitosan extraction processes and solvent types.// J. Food Sci. 2006. V. 71. №2. P. E33.

252. D. A. Miller, et al. The properties of chitosan as a retardant binder in matrix tablets for sustained drug release.// Drug Deliv. Technol. . 2006. V. 6. № 9. P. 44.

253. S. Kida mbi, et al. Selective hydrogenation by Pd nanoparticles embedded in polyelectrolyte multilayers.// J. AM. CHEM. SOC. 2004. V. 126. № 9. P. 2658.

254. G. Kumar, et al. Photoelectron Spectroscopy of Coordination Compounds. II. Palladium Complexes.// Inorg. Chem. 1972. V. 11. № 2. P. 296.

255. Z. Dobrovolna, et al. Competitive hydrogenation in alkene-alkyne-diene systems with palladium and platinum catalysts.// J. Mol. Catal. A: Chem. 1998. V. 130.P. 279.

256. A. Biffis, et al. Relationships between physico-chemical properties and catalytic activity of polymer-supported palladium catalysts II. Mathematical model.// Appl. Catal. A. 1996. V. 142.P. 327.

257. L. M. Bronstein, et al. Structure and Properties of Bimetallic Colloids Formed in Polystyrene-block-Poly-4-vinylpyridine Micelles: Catalytic Behavior in Selective Hydrogenation of Dehydrolinalool.// J. Catal. 2000. V. 196.P. 302.

258. N. V. Semagina, et al. Selective dehydrolinalool hydrogenation with poly(ethylene oxide)-block-poly-2-vinylpyridine micelles filled with Pd nanoparticles.// J. Mol. Cat. A: Chem. 2004. V. 208. № 1-2. P. 273.

259. E. Sulman, et al. Hydrogenation of dehydrolinalool with novel catalyst derived from Pd colloids stabilized in micelle cores of polystyrene-poly-4-vinylpyridine block copolymers.// Appl. Catal.: A. 1999. V. 176.P. 75.