Физико-химическое изучение нанокомпозитных материалов, получаемых темплатно методом управляемого золь-гель синтеза
Диссертация
Темплатный синтез силикатов, впервые проведенный методом золь-гель химии в начале 1990;х годов, позволяет получать неорганические материалы с упорядоченной структурной организацией. Его уникальность заключается в возможности регулирования морфологии синтезируемого материала, что делается посредством изменения темплата. Для этой цели часто используют мицел-лярные и жидкокристаллические структуры… Читать ещё >
Содержание
- Список сокращений
- ГЛАВА 1. ЛИТЕРАТУРНЫЙ ОБЗОР
- 1. 1. Общая характеристика поверхностно-активных веществ
- 1. 1. 1. Основные типы
- 1. 1. 2. Надмолекулярные структуры ПАВ
- 1. 1. 3. Алкилполиглюкозиды
- 1. 1. 3. 1. Физико-химические свойства АПГ
- 1. 1. 3. 2. Фазовое поведение технических марок АПГ
- 1. 1. Общая характеристика поверхностно-активных веществ
- 1. 2. Циклодекстрины
- 1. 2. 1. Строение циклодекстринов
- 1. 2. 2. Комплексы включения «гость-хозяин»
- 1. 2. 3. Гибридные силикатные материалы с циклодекстринами
- 1. 3. Гибридные нанокомпозитные материалы с упорядоченной структурной организацией
- 1. 3. 1. Золь-гель химия
- 1. 3. 1. 1. Гидролиз
- 1. 3. 1. 2. Реакции конденсации
- 1. 3. 1. 3. Золь-гель переход
- 1. 3. 1. 4. Особенности формирования диоксида титана
- 1. 3. 2. Мезопористые силикатные материалы, получаемые методом матричного синтеза
- 1. 3. 1. Золь-гель химия
- 2. 1. Материалы
- 2. 2. Приготовление составов, образцов
- 2. 2. 1. Растворы
- 2. 2. 2. Солюбилизация люминола
- 2. 2. 3. Комплексы включения
- 2. 2. 4. Гидрогели, аэрогели и ксерогели
- 2. 2. 5. Синтез диоксида титана
- 2. 3. Методы исследования
- 2. 3. 1. Динамическая реология 52 2.3.1.1. Определение базовых реологических параметров
- 2. 3. 2. Спектрофотометрия
- 2. 3. 3. Атомно-силовая микроскопия
- 2. 3. 4. Сканирующая электронная микроскопия
- 2. 3. 5. Просвечивающая электронная микроскопия
- 2. 3. 6. Рентгеноструктурный анализ
- 2. 3. 7. Поляризационная микроскопия
- 2. 3. 8. ЯМР-спектроскопия
- 2. 3. 9. рН-метрия
- 2. 3. 10. Азотная порометрия
- 2. 3. 11. Малоугловое рентгеновское рассеяние (МУРР)
- 3. 1. Особенности процессов на циклических олигосахаридах
- 3. 2. Механические свойства
- 3. 3. Морфология
- 3. 4. Молекулярная модель матричного синтеза на ЦД
- 3. 5. Создание сорбентов на основе ЦД
- 4. 1. Особенности золь-гель процессов с участием ТГЭОС и АПГ
- 4. 2. Механические свойства
- 4. 3. Мезопористость
- 4. 4. Исследование наноразмерной структуры нанокомпозитов методом МУРР
- 4. 5. Морфология
- 4. 6. Механизм формирования гибридных силикатных наноматериалов
- 4. 7. Солюбилизация люминола в мицеллярном растворе АПГ
- 4. 8. Синтез гибридного нанокомпозитного материала с флюоресцентными свойствами
- 5. 1. Характеристика структур лецитина как темплата
- 5. 2. Синтез диоксида титана в среде лецитинового органогеля
- 5. 3. Морфология
- 5. 4. Механизм матричного синтеза кристаллического диоксида титана при комнатной температуре
Список сокращений
ПАВ — поверхностно-активные вещества
ТМОС — тетраметоксисилан
ТЭОС — тетраэтоксисилан
ТГЭОС — тетракис (2-гидроксиэтил)ортосиликат
ЦД — циклодекстрин
МГ — молекула «гость»
АПГ — алкилполиглюкозиды
МСМ — мезопористые силикатные материалы
МУРР — малоугловое рентгеновское рассеяние
Список литературы
- Joensson В., Lindman В., Holmberg К., Kronberg В. Surfactants and polymers in aqueous solution. New York, 1998. — 473 p.
- Piorr R. Structure and application of surfactants. In Surfactants in consumer products: theory, technology and application / Ed. J. Falbe. Berlin, Heidelberg: Springer-Verlag, 1987. — P. 5−22.
- Schmalstieg A., Wasow G.W. Anionic surfactants. In Handbook of applied surface and colloid chemistry / Ed. K.Holmberg. New York: John Wiley & Sons, Ltd., 2001.-P. 271−292.
- Cox M.F. Nonionic surfactants. In Handbook of applied surface and colloid chemistry / Ed. K.Holmberg. New York: John Wiley & Sons, Ltd., 2001. — P. 294−308.
- Huber L. Environmental aspects of surfactants. In Handbook of applied surface and colloid chemistry / Ed. K.Holmberg. New York: John Wiley & Sons, Ltd., 2001.-P. 509−535.
- Русанов А.И. Мицеллообразование в растворах поверхностно-активных веществ. СПб.: Химия, 1992. — 280 с.
- Israelachvili J., Mitchel D.J., Ninham B.W.J. Theory self-assembly of hydrocarbon amphiphiles into micelles and bilayers // J. Chem. Soc., Faraday Trans. 1976. — Vol. 72. — P. 1525−1568.
- Israelachvili J., Mitchel D.J., Ninham B.W.J. Theory of self-assembly of lipid bilayers and vesicles // Biochim. Biophys. Acta. 1977. — Vol. 470. — P. 185−201.
- Israelachvili J. The science and applications of emulsions an overview // Colloids surfaces A. — 1994. — Vol. 91. P. 1−8.
- Israelachvili J.N. Intermolecular and surface forces. San Diego, 1991. — 234 p.
- Balzer D. Alkylpolyglucoside, their physico-chemical properties and their uses // Tenside Surf. Det. 1991. — Vol. 28. — P. 419127.
- Hill K., von Rybinski W., Stoll G. Alkyl polyglucosides. Technology, properties and applications. Weinheim: VCH, 1997. — 226 p.
- Fischer E. Yeber die glucosede der alkoho/ // Ber. dt. chem. G. 1893. — Vol. 26.-P. 2400−2412.
- Nilsson F., Soederman O. Physical-chemical properties of the n-octyl (3-D-glucoside/water system. A phase diagram, self-diffusion NMR, and SAXS study // Langmuir. r996~Volrl'2~Pr902=908T~
- Dupuy C., Auvray X., Petipas C. Anomeric effects on the structure of micelles of alkyl maltosides in water // Langmuir. 1997. — Vol. 13. -P. 3965−3967.
- Mesa L.C., Bonincontro A., Sesta B. Solution properties of octyl |3-D glucoside. Part 1: Aggregate size, shape and hydration // Colloid Polym Sci. 1993. — V. 271. -P. 1165−1171.
- Antonelli M.L., Bonicelli M.G., Ceccaroni G., Mesa L.C., Sesta B. Solution properties of octyl-(3-D-glucosie. Part 2: Thermodynamics of micelle formation // Colloid Polym Sci. 1994. — Vol. 272. — P. 704−711.
- Warr G.G., Drummond C.J., Grieser F., Ninham B.W., Evans D.F. Aqueous solution properties of nonionlc n-dodecyl 3-D-maltoside micelles // Journal of Physical Chemistry. 1986. — Vol. 90. — P. 4581−4586.
- Sierra M.L., Svensson M. Mixed micelles containing alkylglycosides: effect of the chain length and the polar head group // Langmuir. 1999. — Vol. 15. — P. 2301— 2306.
- Nilsson F., Soederman O., Reimer J. Phase sparation and aggregate-aggregate interactions in the C9Gi/Ci0Gi (3-alkyl glucosides/water system. A phase diagram and NMR self-diffusion study // Langmuir. 1998. — Vol. 14. — P. 6396−6402.
- Zhang R., Marone P.A., Thiyagarajan P., Tiede D.M. Structure and molecular fluctuations of n-alkyl-|3-D-glucopyranoside micelles determined by X-ray and neutronscatter-ing-//-Langmuir——l-9−9-9i—-Vol—l-5i—Pr-7−5-1−0-751−9^
- Lorber B., Bishop J.B., DeLucas L. Purification of octyl (3-D-glucopyranoside and reestimation of its micellar size // Biochimica et Biophysica Acta. 1990. — Vol. 1023.-P. 254−265.
- Auvray X., Petipas C., Anthore R., Rico-Lattes I., Lattes A. X-ray diffraction study of the ordered lyotropic phases formed by sugar-based surfactants // Langmuir. 1995.-Vol. 11.-P. 433−439.
- Moews P.C., Knox J.R. The crystal structure of 1-Decyl a-D-glucopyranoside: a polar bilayer with a hydrocarbon subcell // J. Am. Chem. Soc. 1976. — Vol. 13. — P. 6628−6633.
- Eidelman O., Blumenthal R., Walter A. Composition of octyl glucoside-phosphatidylcholine mixed micelles // Biochemistry. 1988. — Vol. 27. — P. 28 392 846.
- Rosevear P., VanAken T., Baxter J., Ferguson-Miller S. Alkyl glycoside deteergents: a simpler synthesis and their effects on kinetic and physical properties of cytochrome n oxidase // Biochemistry. 1980. — Vol. 19. — P. 4108−4115.
- Balzer D. Cloud point phenomena in phase behavior of alkyl polyglucosides in water // Langmuir. 1993. — Vol. 9. — P. 3379−3384.
- Platz G., Polike J., Thunig C. Phase behavior, lyotropic phases, and flow properties of alkyl glycosides in aqueous solution // Langmuir. 1995. — Vol. 11. — P. 4250−4255.
- Hoffmann В., Platz G. Phase and aggregation behaviour of alkylglycosides // Cur. Opin. in Solid State & Materials Sci. 2001. — Vol. 6. — P. 171−177.
- Schulte J., Enders S., Quitzsch K. Rheological studies of aqueous alkylpolyglucoside surfactant solutions // Colloid. Polym. Sci. 1999. — Vol. 277. -P. 827−836.
- Егоров H.C., Кесткер А. И., Вокк P.A. История исследования циклодекстринов, свойства и область их применения /ГИтоги науки и техники. Микробиология. 1988. — Т. 20, № 1. — С. 4−51.
- Connors К.А. The stability of cyclodextrin complexes in solution // Chem. Rev.- 1997. Vol. 97. — P. 1325−1357.
- Larsen K.L. Large cyclodextrins // J. Incl. Phenom. Macro. Chem. 2002. -Vol. 43.-P. 1−13.
- Шпигун O.A., Ананьева И. А., Будунова Н. Ю., Шаповалова Е. Н. Использование циклодекстринов для разделения энатиомеров // Успехи химии.- 2003. Т. 72, № 12. — С. 1167−1189.
- Kitagawa M., Hoshi H., Sakurai M., Inoue Y., Chujo R. The large dipole moment of cyclomaltohexaose and its role in determining the guest orientation in inclusion complexes // Carbohydr. Res. 1987. — Vol. 163. — P. 1−3.
- Bako I., Jicsinszky L. Semiempirical calculations on cyclodextrins // J. Inclusion. Phenom. Mol. Recognit. Chem. 1994. — Vol. 18. — P. 275−289.
- Manor P.C., Saenger W. Water molecule in hydrohobic surroundings: structure of a-cyclodextrin-heahydrate (С6Н, о05) б'6Н20 // Nature. 1972. — Vol. 237. — P. 392−393.
- Saenger W. Circular hydrogen bonds // Nature. 1979. — Vol. 279. — P. 343 344.
- Manor P.C., Saenger W. Topography of cyclodextrin inclusion complexes. III. Crystal and molecular structure of cyclohexaamylose hexahydrate, the (H20)2 inclusion complex // J. Am. Chem. Soc. 1974. — Vol. 96. — P. 3630−3639.
- Казачинская Е.П., Баскин И. И., Мамонов П. А., Матвеенко В. Н. «Молекулярное моделирование комплексообразования молекул циклодекстрина и витамина К3 // Вестн. Моск. ун-та. 2006. — Т. 47, № 4. — С. 278−283.
- Steiner Т., Koellner G. Crystalline f3-cyclodextrin hydrate at various humidities: fast, continuous, and reversible dehydration studied by X-ray diffraction // J. Am. Chem. Soc. 1994.-Vol. 116.-P. 5122−5128.
- Fanali S. Enantioselective determination by capillary electrophoresis with cyclodextrins as chiral selectors // J. Chromatogr. A. 2000. — Vol. 875. — P. 89−122.
- Villalonga R., Cao R., Fragoso A. Supramolecular chemistry of cyclodextrins in enzyme technology // Chem. Rev. 2007. — Vol. 107. — P. 3088−3116.
- Tonkova A. Bacterial cyclodextrin glucanotransferase // Enzyme Microb. Technol. 1998. — Vol. 22. — P. 678−686.
- Kitahata S., Tsuyama N., Okada S. Purification and some properties of cyclodextrin glycosyltransferase from a strain of Bacillus species // Agric. Biol. Chem. 1979. — Vol. 38. — P. 387−393.
- Fujita Y., Tsubouchi H., Inagi Y., Tomita K., Ozaki A. Purification and properties of cyclodextrin glycosyltransferase from Bacillus sp. AL-6 // J. Ferment. Bioeng. 1990. — Vol. 70. — P. 150−154.
- Hasimoto H. Present status of industrial application of cyclodextrins in Japan // Journal of Inclusion Phenomena and Macrocyclic Chemistry. 2002. — Vol. 44. — P. 57−62.
- Hedger A.R. Industrial applications of cyclodextrins // Chemical reviews. -1998. Vol. 98. — P. 2035−2044.
- Junior J.M.R., Lima К. M., Jensen C.E.M., Aguiar M.M.G., Junior A.S.C. The effect of cyclodextrins on the in vitro and in vivo properties of insulin-loaded poly (D, L-lactic-co-glycolic acid) microspheres // Artif. Organs. 2003. — Vol. 27. — P. 492197.
- Breslow R. and Dong S.D. Biomimetic reactions catalyzed by cyclodextrins and their derivatives // Chem. Rev. 1998. — Vol. 98. — P. 1997−2011.
- Матвеенко B.H., Волчкова И. Л., Парфеньев A.H., Иванов А. В. Комплексы включения циклодекстринов и их роль в повышении витаминизации пищевых продуктов // Журнал прикладной химии. 1996. — Т. 69, № 5. — С. 808−811.
- Асимов М.М., Бушук Б. А., Сенюк М. А., Ступак А. П., Рубинов А. Н. Исследование особенностей формирования комплекса включения |3-циклодекстрина с родамином 6Ж // Журнал прикладной спектроскопии. 1999. -Т. 66, № 5.-С. 619−621.
- Singh М., Sharma R., Banerjee U.C. Biotechnological applications of cyclodextrins // Biotech. Advanc. 2002. — Vol. 20. — P. 341−359.
- Buschmann H.-J., Cleve E., Schollmeyer E. The interactions between nonionic surfactants and cyclodextrins studied by fluorescence // J. Incl. Phenom. Macro. Chem. 1999. — Vol. 33. — P. 233−241.
- Loukas Y.L. Multiple complex formation of fluorescent compounds with cyclodexttrins: efficient determination and evaluation of the binding constant withimproved fluorometric studies // J. Phys. Chem. B. 1997. — Vol. 101. — P. 48 634 866.
- Harada A. Preperation and structures of supramolecules between cyclodextrins and polymers // Coord. Chem. Rev. 1996. — Vol. 148. — P. 115−133.
- Rekharsky M.V., Inoue Y. Complexation thermodynamics of cyclodextrins // Chemical Reviews. 1998. — Vol. 98. — P. 1875−1917.
- Schneider H.-J., Hacket F., Rudiger V. NMR studies of cyclodextrins and cyclodextrin complexes // Chemical Reviews. 1998. — Vol. 98. — P. 1755−1785.
- Harata K. The structure of cyclodextrin complex. III. The crystal structure of the a-cyclodextrin-sodium benzensulfonate complex // Bull. Chem. Soc. Jpn. 1976. -Vol. 49. — P. 2066−2072.
- Wood D.J., Hruska F.E., Saenger W. NMR study of the inclusion of aromatic molecules in a-cyclodextrin // J. Am. Chem. Soc. 1977. — Vol. 99. — P. 1735−1740.
- Harata K. Crystal structure of the cyclohexaamylose-p-iodophenol complex // Carbohydr. Res. 1976. — Vol. 48. — P. 265−270.
- Harata K. The structure of cyclodextrin complex. V. Crystal structures of a-cyclodextrin complexes with p-nitrophenol and p-hydroxybenzol acid // Bull. Chem. Soc. Jpn. 1977. — Vol. 50. — P. 1416−1424.
- Harata K. The structure of the cyclodextrin complex. IX. The crystal structure of a-cyclodextrin-m-nitroaniline (1:1) hexahydrate // Bull. Chem. Soc. Jpn. 1980. -Vol. 53.-P. 2782−2786.
- Shibakami M., Sekiya A. X-ray crystallographic study of fluorine atom effect on guest orientation inside the a-cyclodextrin cavity // J. Chem. Soc., Chem. Commun. 1992. — Vol. 29. — P. 1742−1743.
- Панова И.Т., Матухина Е. В., Попова Е. И., Герасимов В. И., Топчиева И. Н. Структурная организация комплексов включения (3-циклодекстрина и полипропиленоксида // Высокомолек. соед. А. 2001. — Т. 43, № 7. — С. 1−9.
- Попова Е.И., Топчиева И. Н., Жаворонкова Е. В., Панова И. Г., Матухина Е. В., Герасимов В. И. Два типа инклюзионных комплексов на основе полипропиленоксида и |3-циклодекстрина // Высокомолек. соед. А. 2002. — Т. 44, № i.-p. 85−90.
- Harata К. The structure of the cyclodextrin complex. II. The crystal structure of a-cyclodextrin-methyl orange (2:1) complex // Bull. Chem. Soc. Jpn. 1976. — Vol. 49.-P. 1493−1501.
- Steiner Т., Gessler K. Aromatic molecules included into and containing the outer surface of cyclomaltohexaose (a-cyclodextrin): crystal structure of a-cyclodextrin-(benzyl alcohol)2-hexahydrate // Carbohydr. Res. 1994. — Vol. 260. -P. 27−38.
- Hashimoto S., Thomas J.K. Fluorescence study of pyrene and naphthalene in cyclodextrin-amphiphile complex systems // J. Am. Chem. Soc. 1985. — Vol. 107. -P. 4655−4662.
- Hamai S. Association of inclusion compounds of 3-cyclodextrin in aqueous solution // Bull. Chem. Soc. Jpn. 1982. — Vol. 55. — P. 2721−2729.
- Giorgi J.B., Tee O.S. Cooperative behavior by two different cyclodextrins in a reaction: evidence of biomodal transition state binding // J. Am. Chem. Soc. 1995. -Vol. 117.-P. 3633−3634.
- Ma M., Li D. New organic nanoporous polymers and their inclusion complexes // Chem. Mater. 1999. — Vol. 11. — P. 872−874.
- Sanemasa I., Osajima Т., Deguchi T. Association of C5-C9 normal alkanes with cyclodextrins in aqueous medium // Bull. Chem. Soc. Jpn. 1990. — Vol. 63. — P. 2814−2819.
- Matsui Y., Mochida K. Binding forces contributing to the association of cyclodextrin with alcohol in an aqueous solution // Bull. Chem. Soc. Jpn. 1979. -Vol. 52.-P. 2808−2814.
- Bastos M., Briggner L.-E., Shehatta I., Wadso I. The binding of alkane-a, co-diols to a-cyclodextrin. A microcalorimetric study // J. Chem. Thermody. 1990. -Vol. 22.-P. 1181−1190.
- Scypinski S., Drake J.M. Photophysics of coumarin inclusion complexes with cyclodextrin. Evidence for normal and inverted complex formation // Journal of Physical Chemistry. 1985. — Vol. 89. — P. 2432−2435.
- Lee C., Sung Y.W., Park J.W. Multiple equilibria of phenothiazine dyes in aqueous cyclodextrin solutions // Journal of Physical Chemistry. 1999. — Vol. 103. — P. 893−898.
- Nielsen R., Nielsen J., Larsen K. Distribution and accessibility of cyclodextrins covalently bound onto silica gel // Journal of Inclusion Phenomena and Macrocyclic Chemistry. 2010. — Vol. 67. — P. 399105.
- Liu M., Da S.L., Feng Y.Q., Li L.S. Study on the preparation method and performance of a new |3-cyclodextrin bonded silica stationary phase for liquid chromatography // Analytica Chimica Acta. 2005. — Vol. 533. — P. 89−95.
- Liu M., Li L.S., Da S.L., Feng Y.Q. High performance liquid chromatography with cyclodextrin and calixarene macrocycle bonded silica stationary phases for separation of steroids // Talanta. 2005. — Vol. 66. — P. 479186.
- Zhou Z.M., Fang M., Yu C.X. Synthesis and chromatographic properties of aSchiff bases (6-imino)-(3-cyclodextrin bonded silica for stationary phase of liquid chromatography // Analytica Chimica Acta. 2005. — Vol. 539. — P. 23−29.
- Wang Y., Xiao Y., Yang Tan T.T., Ng S.C. Click chemistry for facile immobilization of cyclodextrin derivatives onto silica as chiral stationary phases // Tetrahedron Letters. 2008. — Vol. 49. — P. 5190−5191.
- Belyakova L., Shvets O., Lyashenko D. Nanosized centers for mercury (II) ions adsorption on a surface of modified silica // Central European Journal of Chemistry. -2008.-Vol. 6.-P. 581−591.
- Belyakova L.A., Kazdobin K.A., Belyakov V.N., Ryabov S.V., Danil de Namor A.F. Synthesis and properties of supramolecular systems based on silica // Journal of Colloid and Interface Science. 2005. — Vol. 283. — P. 488−494.
- Fan Y., Feng Y.Q., and Da S.L. On-line selective solid-phase extraction of 4-nitrophenol with beta.-cyclodextrin bonded silica // Analytica Chimica Acta 2003. -Vol. 484.-P. 145−153.
- Polarz S., Smarsly B., Bronstein L., Antonietti M. From cyclodextrin assemblies to porous materials by silica templating // Angew. Chem. Int. Ed. 2001. — Vol. 23.1. P. 4417−4421.
- Han B.-H., Polaz S., Antonietti M. Cyclodextrin-based porous silics materials as in situ chemical «nanoreactors» from the preparation of variable metal-silica hybrids // Chem. Mater. 2001. — Vol. 13. — P. 3915−3919.
- Han B.-H., Antonietti M. Cyclodexrtin-based pseudopolyrotoxanes as templates for the generation of porous silics materials // Chem. Mater. 2002. — Vol. 14. — P. 3477−3485.
- Han B.-H., Antonietti M. One-step synthesis of copper nanoparticles containing mesoporous silica by nanocasting of binuclear copper (II) complexes with cyclodextrins // Journal of Materials Chemistry. 2003. — Vol. 13. — P. 1793−1796.
- Liu C., Naismith N., Economy J. Advanced mesoporous organosilica material containing microporous (3-cyclodextrins for the removal of humic acid from water // J. Chromatogr. A. 2004. — Vol. 1036. — P. 113−118.
- Huq R., Mercier L., Kooyman P.J. Incorporation of cyclodextrin into mesostructured silica // Chem. Mater. 2001. — Vol. 13. — P. 4512^1519.
- Lu Q., Chen D., Jiao X. Fabrication of mesoporous silica microtubules through the self-assembly behavior of (3-cyclodextrin and triton X-100 in aqueous solution // Chemistry of Materials. 2005. — Vol. 17. — P. 4168−4173.
- Bibby A., Mercier L. Adsorption and separation of water-soluble aromatic molecules by cyclodextrin-functionalized mesoporous silica // Green Chemistry. -2002.-Vol. 5.-P. 15−19.
- Matsui K. Complex formation between pyrene and P-cyclodextrin in sol-gel glasses // Langmuir. 1992. — Vol. 8. — P. 673−675.
- Wang C.X., Chen S. Surface treatment of cotton using p-cyclodextrins sol-gel method // Applied Surface Science. 2006. — Vol. 252. — P. 6348−6352.
- Pierre A.C. Introduction to Sol-Gel Processing. Boston: Kluwer, 1998. — 408 P
- Chujo Y. Organic-inorganic hybrid materials // Current Opinion in Solid State and Materials Science. 1996. — Vol. 1. — P. 806−811.
- Haas K.H., Wolter H. Synthesis, properties and applications of inorganic-organic copolymers (ORMOCERos) // Current Opinion in Solid State and Materials Science. 1999. — Vol. 4. — P. 571−580.
- Hench L.L. Sol-gel materials for bioceramic applications // Current Opinion in Solid State and Materials Science. 1997. — Vol. 2. — P. 604−610.
- Lebeau B., Sanchez C. Sol-gel derived hybrid inorganic-organic nanocomposites for optics // Current Opinion in Solid State and Materials Science. -1999,-Vol. 4.-P. 11−23.
- Lemmon J.P., Lerner M.M. Preparation and characterization of nanocomposites of polyethers and molybdenum disulfide // Chemistry of Materials. 1994. — Vol. 6. -P. 207−210.
- Livage J. Sol-gel processes // Current Opinion in Solid State and Materials Science. 1997. — Vol. 2. — P. N 132−138.
- Lu Z.-L., Lindner E., Mayer A.H. Applications of sol-gel processed interphase catalysts // Chem. Rev. 2002. — Vol. 102. — P. 3543−3578.
- Maschmeyer T. Derivatised mesoporous solids // Current Opinion in Solid State and Materials Science. 1998. — Vol. 3. — P. 71−78.
- Pierre A.C., Pajonk G.M. Chemistry of aerogels and their applications // Chemical Reviews 2002. — Vol. 102. — P. 4243−4266.
- Wallington S.A., Pilon C., Wright J.D. Sol-gel composites for optical sensing of solvent // J. Sol-Gel Sci. Tech. 1997. Vol. 8. — P. 1127−1132.
- Kresge C.T., Leonowicz M.E., Roth W.J., Vartuli J.C., Beck J.S. Ordered mesoporous molecular sieves synthesized by a liquid-crystal template mechanism // Nature. 1999.-Vol. 359.-P. 710−712.
- SakkaS. Handbook Sol-Gel Science and Technology: Processing, Characterization and Application. New York: Kluwer Academic Publisher, 2004. -798 p.
- Brinker C.J., Scherer G.W. Sol-gel science. The physics and chemistry of solgel processing. Boston: Academic Press, 1990. — 912 p.
- Шабанова H.A., Саркисов П. Д. Основы золь-гель технологии нанодисперсного кремнезема. М.: Академкнига, 2004. — 208 с.
- Rao Venkateswara A., Pajonk G.M., Parvathy N.N., Elaloui E. Influence of solgel parameters on transparency and monolithicity of silica aerogels. In Sol-Gel Processing and Applicatios. Attia Y.A. New York, 1994. — P. 237 — 256.
- Стрелко B.B. Механизм полимеризации кремневых кислот // Коллоид, журн. 1970. — Т. 3, № 32. — С. 430−435.
- Holmberg К. Surfactant-templated nanomaterials synthesis // Journal of Colloid and Interface Science. 2004. — Vol. 274. — P. 355−364.
- Attard G.S., Glyde J.C., Goltner C.G. Liquid-crystalline phases as templates for the synthesis of mesoporous silica // Nature. 1995. — Vol. 378. — P. 366−368.
- Patarin J., Lebeau В., Zana R. Recent advances in the formation mechanisms of organized mesoporous materials // Curr. Opinion Colloid. Interf. Sci. 2002. — Vol. 7.-P. 107−115.
- Feng P., Bu X., Pine D.J. Control of pore sizes in mesoporous silica templated by liquid crystals in block copolymer-cosurfactant-water systems // Langmuir. -2000. Vol. 16. — P. 5304−5310.
- Wan Y., Zhao D. On the controllable soft-templating approach to mesoporous silicates // Chemical Reviews. 2007. — Vol. 107. — P. 2821−2860.
- Hoffmann F., Cornelius M., Morell J., Froeba M. Silica-based mesoporous organic-inorganic hybrid materials // Angew. Chem. Int. Ed. 2006. — Vol. 45. — P. 3216−3251.
- El-Safty S.A., Hanaoka T. Microemulsion liquid crystal templates for highly ordered three-dimensional mesoporous silica monoliths with controllable mesopore structures // Chemistry of Materials. 2004. — Vol. 16. — P. 384−400.
- Corma A. From microporous to mesoporous molecular sieve materials and their use in catalysis // Chemical Reviews. 1997. — Vol. 97. — P. 2373−2420.
- Tiemann M. Repeated templating // Chemistry of Materials .- 2007. Vol. 20. -P. 961−971.
- Lin H.P., Kao C.P., Mou C.Y., Liu S.B. Counterion effect in acid synthesis of mesoporous silica materials // The Journal of Physical Chemistry B. 2000. — Vol. 104.-P. 7885−7894.
- Soler-Illia G.J., Sanchez C., Lebeau B., Patarin J. Chemical strategies to design textured materials: from microporous and mesoporous oxides to nanonetworks and hierarchical structures // Chemical Reviews. 2002. — Vol. 102. — P. 4093−4138.
- Huo Q., Margolese D.I., Stucky G.D. Surfactant control of phases in the synthesis of mesoporous silica-based materials // Chemistry of Materials. 1996. -Vol. 8.-P. 1147−1160.
- Selvam P., Bhatia S.K., and Sonwane C.G. Recent advances in processing and characterization of periodic mesoporous MCM-41 silicate molecular sieves // Industrial & Engineering Chemistry Research. 2001. — Vol. 40. — P. 3237−3261.
- Huo Q., Margolese D.I., Ciesla U., Feng P., Gier T., Sieger P., Leon R., Petroff P.M., Schuth F., Stucky G.D. Generalized synthesis of periodic surfactant inorganic composite materials // Nature. 1994. — Vol. 368. — P. 317−321.
- Aramendia M.A., Borau V., Jimenez C., Marinas J.M., Romero F.J. Poly (ethylene oxide)-based surfactants as templates for the synthesis of mesoporous silica materials // Journal of Colloid and Interface Science. 2004. — Vol. 269. — P. 394−402.
- El-Safty S.A., Hanaoka T. Monolithic nanostructured silicate family templated by lyotropic liquid-crystalline nonionic surfactant mesophases // Chemistry of Materials. 2003. — Vol. 15. — P. 2892−2902.
- Tanev P.T., Pinnavaia T.J. A neutral templating route to mesoporous molecular sieves // Science. 1995. — Vol. 267. — P. 761−932.
- Tanev P.T., Pinnavaia T.J. Mesoporous silica molecular sieves prepared by ionic and neutral surfactant templating: a comparison of physical properties // Chemistry of Materials. 1996. — Vol. 8. — P. 2068−2079.
- Higgins S., Kennard R., Hill N., DiCarlo J., DeSisto W.J. Preparation and characterization of non-ionic block co-polymer templated mesoporous silica membranes // Journal of Membrane Science. 2006. — Vol. 279. — P. 669−674.
- Li Z., Chen D., Tu B., Zhao D. Synthesis and phase behaviors of bicontinuous cubic mesoporous silica from triblock copolymer mixed anionic surfactant // Microporous and Mesoporous Materials. 2007. — Vol. 105. — P. 3410.
- Matejka L., Dukh O., Kamisova H., Hlavata D., Spirkova M., Brus J. Block-copolymer organic-inorganic networks. Structure, morphology and thermomechanical properties // Polymer. 2004. — Vol. 45. — P. 3267−3276.
- Soler-Illia G.J.d.A.A., Crepaldi E., Grosso D., Sanchez C.D. Block copolymer-templated mesoporous oxides // Curr. Opinion Colloid. Interf. Sci. 2003. — Vol. 8. -P. 109−126.
- Kipkemboi P., Fogden A., Alfredsson V., Flodstram K. Triblock copolymers as templates in mesoporous silica formation: structural dependence on polymer chain length and synthesis temperature // Langmuir. 2001. — Vol. 17. — P. 5398−5402.
- Wan Y., Shi Y., Zhao D. Supramolecular aggregates as templates: ordered mesoporous polymers and carbons // Chemistry of Materials. 2007. — Vol. 20. — P. 932−945.
- Zhao D., Feng J., Huo Q., Melosh N., Fredrickson G.H., Chmelka B.F., Stucky G.D. Triblock copolymer syntheses of mesoporous silica with periodic 50 to 300 angstrom pores // Science. 1998. — Vol. 279. — P. 548−552.
- Zhao D., Sun J., Li Q., Stucky G.D. Morhological control of highly ordered mesoporous silica SBA-15 // Chem. Mater. 2000. — Vol. 12. — P. 275−279.
- Benmouhoub N., Simmonet N., Agoudjil N., and Coradin T. Aqueous sol-gel routes to bio-composite capsules and gels // Green Chem. 2008. — Vol. 10. — P. 957−964.
- Dunn B., Miller J.M., Dave B.C., Valentine J.S., Zink J.I. Strategies for encapsulating biomolecules in sol-gel matrices // Acta Materialia. 1998. — Vol. 46. -P. 737−741.
- Kim J., Grate W., Wang P. Nanostructures for enzyme stabilization // Chem. Eng. Sci. 2006. — Vol. 61.-P. 1017−1026.
- Shchipunov Y.A. Sol-gel-derived biomaterials of silica and carrageenans // J. Colloid Interface Sci. 2003. — Vol. 268. — P. 68−76.
- Sattler K., Gradzielski M., Mortensen K., Hoffmann H. Influence of surfactant on the gelation of novel ethylene glycol esters of silicic acid // Berichte der Bunsengesellschaft Physikalische Chemie. 1998. — Vol. 102. — P. 1544−1547.
- Mehrotra R.C., Narain R.P. Reactions of tetramethoxy- and triethoxysilanes with glycols // Indian J. Chem. 1967. — Vol. 5. — P. 444−448.
- Meyer M., Fischer A., Hoffmann H. Novel ringing silica gels that do not shrink // The Journal of Physical Chemistry B. 2002. — Vol. 6. — P. 1528−1533.
- Sattler K., Gradzielski M., Mortensen K., Hoffman H. Influence of surfactant on the gelation of novel ethylene glycol esters of silica acid // Ber. Bunsenges. Phys. Chem. 1998. — Vol. 102. — P. 1544−1548.
- Shchipunov Y.A., Karpenko T. Hybrid polysaccharide-silica nanocomposites prepared by the sol-gel technique // Langmuir. 2004. — Vol. 20. — P. 3882−3887.
- Shchipunov Y.A., Kojima A., Imae T. Polysaccharides as a template for silicate generated by sol-gel processess // J. Colloid Interface Sci. 2005. — Vol. 285. — P. 574−580.
- Shchipunov Y., Shipunova N. Regulation of silica morphology by proteins serving as a template for mineralization // Colloids and Surfaces B: Biointerfaces. -2008.-Vol. 63.-P. 7−11.
- Shchipunov Y.A., Karpenko Т., Krekoten A. Hybrid organic-inorganic nanocomposites fabricated with a novel biocompatible precursor using sol-gel processing // Composite Interfaces. 2005. — Vol. 11. — P. 587−607.
- Shchipunov Yu.A. Entrapment of biopolymers into sol-gel-derived silica nanocomposites // Bio-inorganic hybrid nanomaterials / Eds. Ruiz-Hitzky E., Ariga K., Lvov Yu.M. Weinheim: WILEY-VCH Verlag, 2008. — P. 75−117.
- Shchipunov Y.A., Karpenko T.Y., Krekoten A.V., Postnova I.V. Gelling of otherwise nongelable polysaccharides // Journal of Colloid and Interface Science. -2005. Vol. 287. — P. 373−378.
- Шрамм Г. Основы практической реологии и реометрии. М.: КолосС, 2003.-312 с.
- Бибик Е.Е. Реология дисперсных систем. Л.: Ленинградский университет, 1981. — 172 с.
- Кулезнев В.Н., Шершнев В. А. Химия и физика полимеров. М.: Высшая школа, 1988.- 312 с.
- Рейнер М. Реология. М.: Наука, 1965. — 224 с.
- Ш. Каргин В. А. Краткие очерки по физикохимии полимеров. М.: Химия, 1967.-231 с.
- Winter H.H., Chambor F. Analysis of linear viscoelasticity of crosslinking polymer at the gel point // J. Rheol. 1986. — Vol. 30. — P. 367−382.
- Larson R.G. The structure and rheology of complex fluids. New York: Oxford University Press, 1999. — 688 p.
- Ferry J.D. Viscoelastic properties of polymers. New York: John Wiley, 1980. -188 p.
- Goodwin J.W., Hughes R.W. Rheology for chemists. Cambridge: Royal Society of Chemistry, 2000. — 290 p.
- Бартенев Г. М., Бартеньева А. Г. Релаксационные свойства полимеров. М.: Химия, 1992.-384 с.
- Грет С., Синг К. Адсорбция, удельная поверхность, пористость. М.: Мир, 1984.-306 с.
- Карнаухов А.П. Адсорбция. Текстура дисперсных и пористых материалов.- Новосибирск: Наука. Сибирское предприятие РАН, 1999. 470 с.
- Szejtli J. Introduction and general overview of cyclodextrin chemistry // Chemical Reviews. 1998. — Vol. 98. — P. 1743−1753.
- Szejtli J. Cyclodextrin and their inclusion complexes. Budapest: Academia Kiado, 1982.-296 p.
- Hench L.L., West J.K. The sol-gel process // Chem. Rev. 1990. — Vol. 90. — P. 33−72.
- Ferry J.D. Viscoelastic properties of polymers. New York: John Wiley, 1980.- 188 p.
- Uekama К., Hirayama F., Irie T. Cyclodextrin drug carrier systems // Chemical Reviews. 1998. — Vol. 98. — P. 2045−2076.
- Okada K. Preparation and characterization of xerogels. In Encyclopedia of surface and colloid science. New York, 2002. — P. 4292 — 4305.
- Панова И.Г., Герасимов В. И., Топчиева И. Н. Структурообразование в системе а-циклодекстрин-полиэтиленоксид-вода // Высокомолек. соед. А. -1998. Т. 40, № 10. — С. 1681−1686.
- Harada A., Li J., Kamachi М. Preparation and properties of inclusion complexes of polyethylene glycol with.alpha.-cyclodextrin // Macromolecules. 1993. — Vol. 26.-P. 5698−5703.
- Harada A., Kamachi M. Complex formation between poly (ethylene glycol) and a-cyclodextrin // Macromolecules 1990. — Vol. 23. — P. 2821−2823.
- Coradin Т., Livage J. Synthesis and characterization of alginate/silica biocomposites // Journal of Sol-Gel Science and Technology. 2003. — Vol. 26. — P. 1165−1168.
- Lubda D., Cabrera K., Nakanishi K., Lindner W. Monolithic silica columns with chemically bonded-cyclodextrin as a stationary phase for enantiomer separations of chiral pharmaceuticals // Anal. Bioanal. Chem. 2003. — Vol. 377. — P. 892−901.
- Hirashima H., Imai H., Fukui Y. Structure of hybrid silica gels incorporated with hydrophobic dye molecules // Journal of Sol-Gel Science and Technology. -2003.-Vol. 26.-P. 383−388.
- Liu C., Lambert J.B., Fu L. A Novel family of ordered, mesoporous inorganic/organic hybrid polymers containing covalently and multiply bound microporous organic hosts // Journal of the American Chemical Society. 2003. -Vol. 125.-P. 6452−6461.
- Windsor C. An introduction to small-angle neutron scattering // Journal of Applied Crystallography. 1988. — Vol. 21. — P. 582−588.
- Свергун Д.И., Фейгин JI.A. Рентгеновское и нейтронное рассеяние лучей. -М.: Наука, 1986. 280 с.
- Svergun D. Mathematical methods in small-angle scattering data analysis // Journal of Applied Crystallography. 1991. — Vol. 24. — P. 485−492.
- Semenyuk A.V., Svergun D.I. GNOM a program package for small-angle scattering data processing // Journal of Applied Crystallography. — 1991. — Vol. 24. -P. 537−540.
- Svergun D. Restoring three-dimensional structure of biopolymers from solution scattering // Journal of Applied Crystallography. 1997. — Vol. 30. — P. 792−797.
- Konarev P.V., Volkov V.V., Sokolova A.V., Koch M.H.J., Svergun D.I. PRIMUS: a Windows PC-based system for small-angle scattering data analysis // Journal of Applied Crystallography. 2003. — Vol. 36. — P. 1277−1282.
- Kricka L.J. Clinical applications of chemiluminescence // Analytica Chimica Acta. 2003. — Vol. 500. — P. 279−286.
- Kandimalla V.B., Tripathi V.S., Ju H. Immobilization of biomolecules in solgels: biological and analytical applications // Critical Reviews in Analytical Chemistry. 2006. — Vol. 36. — P. 73−106.
- Vasilescu M., Constantinescu Т., Voicescu M., Lemmetyinen H., Vuorimaa E. Spectrophotometric study of luminol in dimethyl sulfoxide-potassium hydroxide // Journal of Fluorescence. -2003. Vol. 13. — P. 315−322.
- Сумм Б.Д. Основы коллоидной химии. М.: Академия, 2007. — 239 с.
- Griffiths Р.С., Stilbs Р, Paulsen К, Howe A.M., Ptt A.R. FT-PGSE NMR study of mixed micellization of an anionic and a sugar-based nonionic surfactant // J. Phys. Chem. B. 1997. — Vol. 101. — P. 915−918.
- Li В., Zhang Z., Jin Y. Chemiluminescence flow biosensor for hydrogen peroxide with immobilized reagents // Sens. Actuators B. 2001. — Vol. 72. — P. 115−119.
- Ramos M.C., Torijas M.C., Diaz N.A. Enhanced chemiluminescence biosensor for the determination of phenolic compounds and hydrogen peroxide // Sens. Actuators B. 2001. — Vol. 73. — P. 71−75.
- Diaz N.A., Sanchez F.G., Ramos M.C., Torijas M.C. Horseradish peroxidase sol-gel immobilized for chemiluminescence mesasurements of alkaline-phosphatase activity // Sens. Actuators B. 2002. — Vol. 82. — P. 176−179.
- Hanahan D.J. A guide to phospholipid chemistry. New York: Oxford University Press, 1997. — 224 p.
- Tocanne J.-F., Teissie J. Ionization of phospholipids and phospholipid-supported interfacial lateral diffusion of protons in membrane model systems // Biochimica et Biophysica Acta (BBA) Reviews on Biomembranes. — 1990. — Vol. 1031. — P. 111 142.
- Щипунов Ю.А. Самоорганизующиеся структуры лецитина // Успехи химии. 1997. — Т. 66, № 4. — С. 328−352.
- Bergenstahl В., Fontell К. Phase equilibria in the system soybean licithin/water // Progr. Colloid. Polym. Sci. 1983. — Vol. 68. — P. 48−52.
- Dervichian D.G. The physical chemistry of phospholipids // Progress in Biophysics and Molecular Biology. 1964. — Vol. 14. — P. 263−269.
- Elworthy P.H., Mcintosh D.S. The interaction of water with lecithin micelles in benzene // The Journal of Physical Chemistry. 1964. — Vol. 68. — P. 3448−3452.
- Walde P., Giuliani A.M., Boicelli C.A., Luisi P.L. Phospholipid-based reverse micelles // Chemistry and Physics of Lipids. 1990. — Vol. 53. — P. 265−288.
- Blei I., Lee R.E. The differential solubilization of potassium and sodium dye sails by lecithin micelles in benzene // The Journal of Physical Chemistry. 1963. -Vol. 67. — P. 2085−2088.
- Kumar V.V., Raghunathan P. Spectroscopic investigations of the water pool in lecithin reverse micelles // Lipids. 1986. — Vol. 21. — P. 764−768.
- Scartazzini R., Luisi P.L. Organogels from lecithins // The Journal of Physical Chemistry. 1988. — Vol. 92. — P. 829−833.
- Shchipunov Y. Lecithin organogel: A micellar system with unique properties // Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2001. — Vol. 183−185.-P. 541−554.
- Cates M.E. Reptation of living polymers: dynamics of entangled polymers in the presence of reversible chain-scission reactions // Macromolecules. 1987. — Vol. 20. — P. 2289−2296.
- Cates M.E. Nonlinear viscoelasticity of wormlike micelles (and other reversibly breakable polymers) // The Journal of Physical Chemistry. 1990. — Vol. 94. — P. 371−375.
- Шумилина Е.В., Хромова Ю. Л., Щипунов Ю. А. Структура лецитиновых органогелей по данным метода ИК-спектроскопии с Фурье-преобразованием // Журн. физ. хим. 2000. — Т. 74, № 7. — С. 1210−1219.
- Shchipunov Y.A., Shumilina E.V. Lecithin bridging by hydrogen bonds in the organogel // Materials Science and Engineering: C. 1995. — Vol. 3. — P. 43−50.
- Shchipunov Y., Hoffmann H. Indicative evidence for coexistence of long and short polymer-like micelles in lecithin organogel from rheological studies // Langmuir. 1999. — Vol. 15. — P. 7108−7110.
- Cirkel P.A., Koper G.J.M. Characterization of lecithin cylindrical micelles in dilute solution // Langmuir. 1998. — Vol. 14. — P. 7095−7103.
- Schurtenberger P., Scartazzini R., Luisi P.L. Viscoelastic properties of polymerlike reverse micelles // Rheol. Acta. 1989. — Vol. 28. — P. 372−381.
- Щипунов Ю.А. Лецитиновые органогели: реологические свойства полимероподобных мицелл, образующихся в присутствии воды // Коллоид, журн. 1995. — Т. 57, № 4. — С. 591−595.
- Lewis R.N.A.H., McElhaney R.N., Pohle W. Components of the caabonyl stretching band in the infrared spectra of hydrated 1,2-diacylglycerolipid bilayers: a reevalution // Biophys. J. 1994. — Vol. 67. — P. 236−2375.
- Shchipunov Y.A., Shumilina E.V., Ulbricht W., Hoffmann H. The branching of reversed polymer-like micelles of lecithin by sugar-containing surfactants // Journal of Colloid and Interface Science. 1999. — Vol. 211. — P. 81−88.
- Crikel P.A., van der Ploeg J.P.M., Koper G.J.M. Branching and percolation in lecithin wormlike micelles studied by dielectric spectroscopy // Physical Review E. -1998. Vol. 57. — P. 6875−6878.
- Shchipunov Y., Hoffmann H. Growth, branching, and local ordering of lecithin polymer-like micelles // Langmuir. 1998. — Vol. 14. — P. 6350−6360.
- Dierking I. Texures of liquid crystals. Weinheim: Wiley-VCH, 2003. — 220 p.
- Самсонов Г. В. Физико-химические свойства окислов. М.: Металлургия, 1978.-472 с.
- Shchipunov Y., Krekoten A. Crystalline titania nanoparticles synthesized in nonpolar La- lecithin liquid-crystalline media in one stage at ambient conditions // Colloids and Surfaces B: Biointerfaces. 2011. — Vol. 87. — P. 203−208.