Generation of knock-out cells by using CRISPR/Cas9

Como sugestões de ampliar este estudo e para trabalhos futuros propõem-se:

 Avaliar melhor o método de aplicação dos filmes e testar outros métodos de aplicação.

 Caracterizar os nanocompósito por MEV, para explicar melhor como se encontra a dispersão das nanopartículas na matriz polimérica.

ANEXOS

Anexo I: Espectros de UV-vis dos nanocompósitos com (a) 0,5 %, (b) 1%, (c) 1,5% e (d) 2% de TiO2 antes e após envelhecimento UV por 180 minutos.

400 500 600 700 800 900 -0,005 0,000 0,005 0,010 0,015 0,020 0,025 0,030 Ab so rb ân cia (% ) Comprimento de Onda (nm) 0 min. 180 min. 0 2 4 6 8 10 0 2 4 6 8 10 (a) 400 500 600 700 800 900 0,000 0,005 0,010 0,015 0,020 0,025 0,030 0,035 0,040 Ab so rb ân cia (% ) Comprimento de Onda (nm) 0 min. 180 min. 0 2 4 6 8 10 0 2 4 6 8 10 (b)

400 500 600 700 800 900 0,000 0,005 0,010 0,015 0,020 0,025 0,030 0,035 0,040 Ab so rb ân cia (% ) Comprimento de Onda (nm) 0 min. 180 min. 0 2 4 6 8 10 0 2 4 6 8 10 (c) 400 500 600 700 800 900 0,000 0,005 0,010 0,015 0,020 0,025 0,030 0,035 Ab so rb ân cia (% ) Comprimento de Onda (nm) 0 min. 180 min. 0 2 4 6 8 10 0 2 4 6 8 10 (d)

Capítulo VI

5 REFERENCIAS

AARIK, Jaan; AIDLA, Aleks; SAMMELSELG, Vaino; UUSTARE, Teet; RITALA, Mikko; LESKELA, Markku. Characterization of titanium dioxide atomic layer growth from titanium ethoxide and water. Thin Solid Films, v. 370, p. 163-172, 2000.

AKHTAR, M. K.; VEMURY, S.; PRATSINIS, S. E. The role of electrolytes during aerosol synthesis of TiO2. Nanostruct Mater. v. 4, p. 537, 1994.

ALBU, S.P.; GHICOV Andrei; MACAK, Jan M.; HAHN, R; SCHMUKI, Patriki. Self- organized, free-standing TiO2 nanotube membrane for flow-through photocatalytic applications. Nano Lett, 128 p.6–9, 2007.

ALEXANDRE, Michael; DUBOIS, Philippe; PLUTA , Miroslaw; JERÔME, Robert. Metallocene catalyzed polymerization of ethylene in the presence of graphife.

Macromolecular Chemistry and Physics, v. 202, 2239-2246, 2001.

ALEXANDRU, M.; CAZACU, M.; DOROFTEI, F.; IGNAT, M.; TIMPU, D.; GRIPORAS, C.V.; SIMIONESCU, B.C. On the morfology and potential application of polydimethylsiloxane-silica-titania composites. Express Polymers Letters, v. 5, p. 188-196, 2011.

ALMEIDA, M. P. S.; CAIADO, K. L.; SARTORATTO, P. P. C.; SILVA, D. O. C.; PEREIRA, A. R.; MORAIS, P. C. Preparation and size-modulation of silica-coated maghemite nanoparticles. Journal of Alloys and Compound, v.500, p. 149-152, 2010.

ALMQUIST, Catherine; BISWAS Pratim. The photo-oxidation of cyclohexane on titanium dioxide: an investigation of competitive adsorption and its effects on product formation and selectivity. Applied Catalysis A: General, v. 214, p. 259-271, 2001. ALONSO, J. G.; ALONSO, C. G.; POVH, N. P.; SANTOS, O. A. A. XIX Simpósio

Iberoamericano de Catálisis-XIX SICAT, Mérida-Yucatán-México, 1, 1-8, 2004.

ANDERSSON, M.; OSTERLUND, L.; LJUNGSTROM, S.; PALMQVIST, A. Preparation of nanosize anatase and rutile TiO2 by hydrothermal treatment of microemulsions and their activity for photocatalytic wet oxidation of phenol. J. Phys. Chem. B 106, p.10674-10679, 2002.

ASGHAR, W.; QAZI, I. A.; ILYAS, H.; KHAN, A. A.; AWAN, A. M.; ASLAM, R. M. Comparative solid phase photocatalyc degradation of polythene films with doped and undoped TiO2 nanoparticles. Journal of nanomaterials, p. 1-8, 2011.

ASHBY, M.F., FERREIRA, P.J. and SCHODEK, D.L. Nanomaterials, Nanotechnologies and Design: An Introduction for Engineers and Architects,

BALAKRISHNAN, P.A.; ARUNAGIRI, A.; RAO, P.G. Ozone generation by silent electricdischarge and its application in tertiary treatment of tannery effluente. Journal

o Electrostatics. v. 56, p. 77-86, 2002.

BALCIOGLU, I.A.; ÖTKER, M. Treatment of pharmaceutical wastewater containing antibiotics by O3 and O3/H2O2 processes. Chemosphere, v. 50, p. 85-95, 2003. BERNARDO, Paulo R. A.; CARVALHO, Antonio J. F.; PESSAN, Luiz A. Preparação de nanocompósitos de polietileno De baixa densidade com nanopartículas de Dióxido de titânio anatase a partir de Suspensões coloidais. Anais do 10o _Congresso

Brasileiro de Polímeros – Foz do Iguaçu, PR – Outubro, 2009.

BRUNI, S.; CARIATI, F.; CASU, M.; LAI, A.; MUSINU, A.; PICCALUGA, G.; SOLINAS, S. IR and NMR of nanoparticle-support interactions in a Fe2O3 – SiO2 nanocomposite prepared by a sol-gel method. Nanostructured Materials. v. 11, p.573-586, 1999.

BRYAN, J. D.; HEALD, S. M.; CHAMBERS, S. A.; GAMELIN, D. R. Strong room temperature ferromagnetism in Co2+-doped TiO2 made from colloidal nanocrystals.

Journal of American Chemical Society. v. 126, p. 11640-11647, 2004.

BU, S. J.; JIN, Z. G.; LIU, X. X.; YANG, L. R.; CHENG, Z. J. Synthesis of TiO2 porous thin films by polyethylene glycol templating and chemistry of the Process. J.

Cheng, J. Eur. Ceram. Soc. 25, p. 673, 2005.

BURKARTER, E.; SAUL, C.K.; THOMAZI, F.; CRUZ, N.C.; ROMAN, L.S.; SCHREINER, W.H.; Superhydrofobic electrosprayed PTFE. Surface & Coatings

Technology, v. 202, p.194-198, 2007.

BYRAPPA, K.; YOSHIMURA M. Handbook of hydrothermal technology: A technology for crystal growth and materials processing. William Andrew Publishing LLC, New York, 2001.

BYRNE, M. T.; McCARTHY, J. E.; BENT, M.; BLAKE, R.; GUN’KO, Y. K.; HORVATH, E.; KONYA, Z.; KUKOVECZ, A.; KIRICSI, I.; COLEMAN, J.N. Chemical functionalisation of titania nanotubes and their utilisation for the fabrication of reinfirced polystyrene composites. Journal of materials chemistry. v. 17, p. 2351- 2358, 2007.

CABRERA, M. I.; NEGRO, A. C.; ALFANO, O. M.; CASSANO, A. E. Photocatalytic reactions involving hydroxyl radical attack. II. Kinetics of the decomposition of trichloroethylene using titanium dioxide. Journal of Catalysis. 172, p. 380- 390,

1997.

CAITEANU, D.; GYÖRGY, E.; GRIGORESCU, S.; MIHAILESCU, I. N.; PRODAN, G.; CIUPINA, V. Growth of oxide thin films for optical gas sensor applications. Applied

Surface Science, v. 252, p. 4582-4586, 2006

CARP, O.; HUISMAN, C. L.; RELLER, A. Photoinduced reactivity of titanium dioxide.

CASTAÑEDA, L.; ALONS, L.C.; ORTIZ, A.; ANDRADE, E.; SANIGER, J.M.; RAÑUELOS, J.G. Spray pyrolysis deposition and characterization of titanium oxide thin films. Materials Chemistry Physics, v. 77, p. 938-944, 2002.

CAVALHEIRO, A.; BRUNO, J.; SAEKI, M.; VALENTE, J.; FLORENTINO, A. Effect ofScandium on the Strutural and Photocatalytic Properties of Titanium Dioxide Thin CHAMBERS, S. A. Ferromagnetism in doped thin-film oxide and nitride semiconductors and dielectrics. Surface Science Reports, v. 61, p. 345-381, 2006. CHEN, Q.; ZHOU, W.; DU, G.H.;PENG, L. M. Trititanate nanotubes made via a single alkali treatment. Advanced materials, v. 14, n. 17, p. 1208-1211, 2002.

CHOI, W.; KO, J. Y.; PARK, H.; CHUNG, J. S. Investigation on TiO2-coated optical fibers for gas-phase photocatalytic oxidation of acetone. Applied Catalysis B:

Environmental, v. 31, p. 209-220, 2001.

CHOONEE, K.; SYMS, R. R. A.; AHMAD, M. M.; ZOU, H. Post processing of microstructures by PDMS spray deposition. Sensors and Actuators A, 155, 253– 262, 2009.

CORDEIRO, Ana Cristina; LEITE, Selma Gomes Ferreira; DEZOTTI, Marta. “Inactivação por oxidação fotocatalítica de Escherichia coli E Pseudomonas sp”.

Quimica Nova, 27, 689-694, 2004.

COSTA, Ana Cristina F. Melo; VILAR, M. A.; LIRA, Hélio Lucena; KIMINAMI, Ruth Herta G. Aliaga; GAMA, Lucianna. Síntese e caracterização de nanopartículas de TiO2. Cerâmica, 52, p. 255-259, 2006.

COSTA, Célia Domingues. Hematita: um novo método de síntese para a Indústria.

Dissertação de mestrado,São Paulo, 2011.

COSTA, T. H.; FEITOR, M. C.; SOUZA, J. M. B. V. S.; ALVES Jr, C.; SILVA, M. A. A. Elaboration of na apparatus determining contact angle and surface tension, 4°

Encontro de Sociedade Brasileira de Pesquisa em Materiais _{– SBPMAT, Anais}

de congresso, 2003.

CUI, L.; HUI, K.N.; HUI, K.S.; LEE, S.K.; ZHOU, W.; WAN, Z.P.; THUC, Chi-Nhan Ha. Facile microwave-assisted hydrothermal synthesis of TiO2 nanotubes. Materials

Letters, 75, p. 175–178, 2012.

DABROWSKI, B.; ZALESKA, A.; JANCZAREK, M.; HUPKAA, J.; MILLER, J. D. Photooxidation of dissolved cyanide using TiO2 catalyst. Journal of

Photochemistry and Photobiology A: Chemistry, v. 151, p. 201-205, 2002.

DAS, B. N.; KRISHANA, K. On the surface photoconductivity of sintered titanium dioxide pellet. Journal of Materials Science, v. 34, p. 3997-4000, 1999.

DELMAN, A. D.; LANDY, M.; SIMMS, B. B. Photodecomposition of polymethylsiloxane. Polym. Sei., part A-1, v. 7, p. 3375-3386,1969.

DIEBOLD, U. The surface science of titanium dioxide. Surface Science Reports. v. 48, p. 53- 229, 2003.

DING, Xiaofeng; ZHO, Shuxue; WU, Limin; GU, Guangxin; YANG, Jintian. Formation of supra-amphiphilic self-cleaning surface through sun-illumination of titania-based nanocomposite coatings. Surface & Coatings Technology, 205, p. 2554–2561, 2010.

DOONG, R. A.; CHANG, P. Y.; HUANG, C. H. Microstructural and photocatalytic properties of sol-gel-derived vanadium-doped mesoporous titanium dioxide nanoparticles. Journal of Non-Crystalline Solids. v.355, n.45-47, p.2302-2308, 2009.

DUBROVINSKY, L. S.; DUBROVINSKAIA, N. A.; SWAMY, V.; MUSCAT, J.; HARRISON, N. M.; AHUJA, R.; HOLM, B.; JOHANSSON, B. The hardest known oxide. Nature, v. 410, p. 653-654, 2001.

ESTEVES, Ana Catarina C.; TIMMONS, Ana Barros; TRINDADE, Tito. Nanocompósitos de matriz polimérica: estratégias de síntese de materiais híbridos.

Quimica Nova, Vol. 27, No. 5, 798-806, 2004.

FERNANDES, Isabel Margarida Duarte. “Aplicação de compósitos de TiO2 em carvão ativado na fotodegradação do fenol com luz ultravioleta”. Tese (mestrado), Universidade Nova de Lisboa, 2009.

FERREIRA, Odair Pastor. Nanotubos e nanobastões de Óxidos e Sulfetos de Metais de Transição obtidos via Sistemas Bidimensionais (Lamelares): Preparação, Caracterização e Propriedades. 176 f. Tese (Doutorado), São Paulo, 2006.

Films. Journal of Materials Science. v. 43, p. 602-608, 2008.

FOX, M. A.; DULAY, M. T. Heterogeneous photocatalysis. Chem. Rev. v.93, 341-357,

1993.

GENOVESE, A.; SHANKS, R.A. Fire performance of poly (dimethylsiloxane) composites evaluated by cone calorimetry. Composites Part A: applied science

and manufacturing, v.39, p. 398-405, 2008.

GOI, A.; TRAPIDO, M. Hydrogen peroxide photolysis, Fenton reagent and photo- Fenton for the degradation of nitrophenols: a comparative study. Chemosphere, v. 46, p. 913-922, 2002.

GOPAL, M.; MOBERLY CHAM, W. J. J. Room temperature synthesis of crystalline metal

oxides. J. Mater. Sci. v.32, p. 6001, 1997.

GOUVEIA, P. S.; ESCOTE, M. T.; LONGO, E.; LEITE, E.R.; CARRENO, N. L. V.; FONSECA, F. C.; JARDIM, R. F. Química Nova, 28, p. 842-846, 2005.

HAMMING, L. M.; QIAO, R.; MESSERSMITH, O. B.; BRINSON, L. C. Effects of dispersion and interfacial modification on the macroscale properties of TiO2 polymer-

marix nanocomposites. Composite Science and Technology, v. 69, p. 1880-1886, 2009.

Hashimoto, K.; Irie, H.; Fujishima, A. TiO2 photocatalysis: a historical overview and future

prospects. Jpn J. Appl. Phys., 44, p. 8269-8285, 2005.

HENCH, L.L.; WEST, J. K. The sol-gel process. Chem Rev. 90, p. 33-72,1990.

Heywood. Textile Finishing, Society of dyers and colourests, England, 2003.

HU, X.; LI, G.; YU, J.C. Design, fabrication, and modification of nanostructured semiconductor materials for environmental and energy applications. Langmuir, 26,

p. 3031_{–3039, 2010.}

HUANG, Chun-Hsien; YANG, Yen-Tung; DOONG, Ruey-An. Microwave-assisted hydrothermal synthesis of mesoporous anatase TiO2 via sol–gel process for dye- sensitized solar cells. Microporous and Mesoporous Materials, 142, p. 473–480, 2011.

HUANG, H.; LUO, H. J.; YAO, X. Acta Phys. Sin. v. 51, p. 1881, 2002, (in chinese). IKEZAWA, S.; HOMYARA, H.; KUBOTA, T.; SUZUKI, R.; KOH, S.; MUTUGA, F.; YOSHIOKA, T.; NISHIWAKI, A.; NINOMIYA, Y.; TAKAHASHI, BABA, M.; KIDA, K. K., HARA, T.; FAMAKINWA, T. Applications of TiO2 film for environmental purification deposited by controlled electron beam-excited plasma.Thin Solid Films 386, p. 173, 2001.

IKEZAWA, S; HOMYARA, H. Applications of TiO2 film for environmental purification deposited by controlled electron beam-excited plasma. Thin Solids Films, v. 386, p. 173-176, 2001.

IRIE, H.; MORI, H.; HASHIMOTO, K. Interfacial structure dependence of layered TiO2/WO3 thin films on the photoinduced hydrophilic property. Vacuum, v. 74, p. 625-629, 2004.

JENNINGS, J. R.; GHICOV, A.; PETER, L. M.; SCHMUKI, P.; WALKER, A. B. Dye- sensitized solar cells based on oriented TiO2 nanotube arrays: transport, trapping, and transfer of electrons. J Am Chem Soc. 130, 64–72, 2008.

JUNG, K. Y.; PARK, S. B.; HEE, D. J. Phase control and photocatalytic properties of nanosized titania particles by gas-phase pyrolysis of TiCl4. Catalysis

Communications, v. 5, p. 491–497, 2004.

KASUGA, T.; HIRAMATSU, M.; HOSON, A.; SEKINO, T.; NIIHARA, K. Formation of titanium oxide nanotube. Langmuir,14, p. 3160-3163, 1998.

KEMP, T. J.; MCINTYRE, R. A. Mechanism of action of titanium dioxide pigment in the photodegradation of poly(vinyl chloride) and other polymers. Progress In

KIM, E.Y.; PARK, J. H.; HAN, G. Y. Design of TiO2 nanotube array-based water- splitting reactor for hydrogen generation. J Power Sources,184, p. 284, 2008

KOMAMENI, S. “ Nanophase materials by hydrothermal, microwave-hydrothermal and microwave-solvothermal methods”. Current Science, vol. 85, p.1730, 2003. KUMAR, K-N. P.; ZASPALIS, V.T.; KEIZER, K.; BURGGRAAF A.J. Drying process in the formation of sol-gel-derived TiO2 ceramic membrane. Journal of Non-

Crystalline Solids, v.147, p. 375-381, 1992.

Lachheb, H., Puzenat, E., Houas, A. Ksibi, M., Elaloui, E., Guillard, C., Herrmann, J.M. Photocatalytic degradation of various types of dyes (Alizarin S, Crocein Orange G, Methyl Red, Congo Red, Methylene Blue) in water by UV-irradiated titania.

Applied Catalysis B: Environmental, 39, p. 75–90, 2002.

LAGALY, G. Introdution: from Clay mineral-polymer interactions to Clay mineral- polymer nanocomposites. Applied Clay Science, 15, p. 1-9, 1999.

LESSING, P. A. ; Mixed-Cation oxide powders via polymeric precursors. American

Ceramic Society. 68, p.1002-1007, 1989.

LEWICKI, J.P.; LIGGAT, J.J.; PATEL, M. The thermal degradation behaviour of polydimethylsiloxane / montmorillonite nanocamposites. Polymer Degradation and

Stability, v.94, p.1548 -1557, 2009.

LINSEBIGLER, A. L.; LU, G.; YATES, J. T. Photocatalysis on TiOn Surfaces: Principles, Mechanisms, and Selected Results. Chem. Rev. 95, p. 735, 1995.

LIPTAY, G.; NAGY, J.; WEIS, J. Ch.; BORBÉLY, A. KUSZMANN. Thermoanalytical investigations of silicone caoutchouc polymers and silicone rubbers. Journal of

thermal analysis. v. 32, p. 1421-1433,1987.

LUZ, A.P.; RIBEIRO, S.; PANDOLFELLI, V.C. Use of the wettability in the investigation of the corrosion behaviour of the refractory materials. Cerâmica, v.54, p. 174-183, 2008.

MA, Peng-Cheng; MO, Shan-Yin; TANG, Ben-Zhong; KIM, Jang-Kyo. Dispersion, interfacial interaction and re-aglomeration of functionalized carbon nanotubes in epoxy composites. Canbon, v. 48, p. 1824-1834, 2010.

MALAGUTTI, A. R.; MOURÃO, H. A. J. L.; GARBIN, J. R.; RIBEIRO, C.; Deposition of TiO2 and Ag: TiO2 thin films by the polymeric precursor method and their application in the photodegradation of textile dyes. Appl. Catal. B: Environ., 2008. MARK, J.E.; ALLCOCK, H.R.; WEST, R. Polysiloxanes and Related Polymers. In: Inorganic Polymers. Second Edition. New York: Oxford University Press, p. 169 – 268, 2005.

MAZZARION, I.; PICCINI, P. Photocatalytic oxidation of organic acids in aqueous media by a supported catalyst. Chemical Engineering Science, v. 54, p. 3107- 3111, 1999.

MENEGHETTI, P.; QUTUBUDDI, S. Synthesis, thermal propriedades and applications of polymer-clay nanocomposites. Thermochimica Acta, 442, 74-77, 2006.

MOGYORÓSI, K.; FARKAS, A.; DEÁKANY, I. TiO2-based photocatalytic degradation of 2-chlorophenol adsorbed on hydrophobic clay. Environmental Science &

Technology, v. 36, p. 3618-3624, 2002.

MOURÃO, H.A.J.L.; MENDONÇA, V.R. _{“Nanoestruturas em fotocatálise: uma} revisão sobre estratégias de síntese de fotocatalisadores em escala nanométrica”, Departamento de Química, Universidade de São Carlos, 2008.

MOURÃO, Henrique Aparecido de Jesus Loures. Síntese e caracterização de Nanocompósitos magnéticos e sua aplicação na despoluição de águas.

Dissertação de mestrado, São Paulo, 2009.

Multifunctional Materials (Doutorado), Araraquara, 2001.

NAKAJIMA, A.; KOIZUMI, S.; WATANABE, T.; HASHIMOTO, K. Effect of repeated photo-illumination on the wettability conversion of titanium dioxide. Journal of

Photochemistry and Photobiology A: Chemistry, v. 146, p. 129-132, 2001.

NAKATA, Kazuya; FUJISHIMA, Akira. TiO2 photocatalysis: Design and applications. Journal of Photochemistry and Photobiology C: Photochemistry Reviews, p. 21, 2012.

NEWNHAM, R. E. Composite electroceramics. Annu. Rev. Mater. Sci.,16, p. 47-68,

1986.

NUNES, L.C.S. Shear Modulus estimation of the polymer polydimethylsiloxane (PDMS) using digital image correlation. Materials and Design, v. 31, p. 583-588, 2009.

OLIVEIRA, D. B. Análise do Aquecimento por Microondas em uma Cavidade Monomodo Utilizando uma Técnica Semi-Analítica. Tese (mestrado), 90 p. Minas Gerais, 2007.

PASCHOALINO, M.P.: “Utilização da fotocatálise heterogénea na desinfecção de atmosferas confinadas”. Tese (mestrado), Instituto de Química da UNICAMP, São Paulo, 2006

PAULINO, Priscilla Nogueira. Fotorredução catalítica de co2 para geração de produtos de alto teor energético. Tese (mestrado), Rio de Janeiro, 2011.

PAVASUPREE, Sorapong; JITPUTTI, Jaturong; NGAMSINLAPASATHIAN, Supachai; YOSHIKAWA, Susumu. Hydrothermal synthesis, characterization,

photocatalytic activity and dye-sensitized solar cell performance of mesoporous anatase TiO2 nanopowders. Pergamon- Elsevier science LTD, 2008.

Pechini, M. P. Method of Preparing Lead and Alkaline the Same For a Capacitor.U.S. Patent, N° 3.330.697, 1967.

PEDRAZA, F.; VASQUEZ, A. Obtention of TiO2 rutile at room temperature through direct oxidation of TiCl3. Journal of Physics and Chemistry of Solids, v. 60, p. 445-448, 1999.

PERÉS, M.; TORRADES, F. HORTAL, J.A.G.; DOMÉNECH, X.; PERAL, J. Removal of organic contaminats in paper pulp treatment effluents under Fenton and photo- fenton conditions. Applied Catalysis B: Environmental, v. 36, p. 63-74, 2002.

PERIYAT, P.; LEYLAND, N.; MCCORMACK, D.E.; COLREAVY, J.; CORR, D.; PILLAI, S.C. Rapid Microwave Synthesis of Mesoporous TiO2 for Electrochromic

Displays. J. Mater.Chem. 20, p. 3650–3655, 2010.

PUMA, G. L.; GAO, B.; CHEN, G.Z. Carbon nanotubes/titanium dioxide (CNTs/TiO2) nanocomposites prepared by conventional and novel surfactant wrapping sol-gel methods exhibiting enhanced photocatalytic activity. Applied catalysis B:

Environmental. v.89, n. 3, p. 503-509, 2009.

QI, L.; XU, M.X.; TIAN, Y.M.; ZHAO, J.W. Mechanism of scaling on oxidation reactor wall in TiO2 synthesis by chloride process. Transactions of Nonferrous Metals Society of China, v.16, p. 426,2006.

QOURZAL, S.; MALIKA, T.; ASSABBANE, A.; YHYA, A-I. Photocatalytic degradation and adsorption of 2-naphthol on suspended TiO2 surface in a dynamic reactor.

Journal of Colloid and Interface Science, v. 286, p. 621–626, 2005.

QUINA, F. H. Nanotecnologia e o Meio Ambiente: Perspectivas e Riscos. Química

Nova, Vol. 27, No. 6, 1028-1029, 2004.

REDDY, K. M.; MANORAMA, S. V.; REDDY, A. R. Bandgap studies on anatase titanium dioxide nanoparticles. Mater. Chem. Phys. 78, p. 239, 2003.

RIBEIRO, M. A.; NEIVA, L. S.; MAIA, D. F.; OLIVEIRA, J. B. L.; GAMA L. Síntese do TiO2 dopado com Zr por meio do método Pechini: Avaliação dos efeitos da temperatura de calcinação. Revista Eletrônica de Materiais e Processos, v.7.2, p. 111–116, 2012.

RONCONI, C. M.; RIBEIRO, C.; BULHÕES, L. O. S.; PEREIRA, E. C.; Insights for phase control in TiO2 nanoparticles from polymeric precursors method. J. Alloys

and Compd, 466, p. 435-438, 2008.

S.W. Yang, L. Gao. Fabrication and shape-evolution of nanostructured TiO2via a sol- solvothermal process based on benzene-water interfaces. Mater. Chem. Phys. 99, P. 437, 2006.

SANTOS, Silvanice Aparecida Lopes; CAVALHEIRO, Alberto Adriano; AMORESI Rafael Aparecido Ciola; RODRIGUES Daniela Cristina Manfroi. Síntese e caracterização de pós de TiO2 modificados com silício e zircônio preparados pelo

método sol-gel, química/UEMS-naviraí, 2011.

SCHOTTNER, G.; Hybrid Sol-Gel-Derived Polymers: Applications of Multifunctional Materials. Chem. Mater., 13, p. 3422-3435, 2001.

SEN, S.; MAHANTY, S.; ROY, S.; HEINTZ, O.; BOURGEOIS, S.; CHAUMONT, D. Investigation on sol–gel synthesized Ag-doped TiO2 cermet thin films. Thin Solid

Films, v. 474, p. 245-249, 2005.

SIGOLI, F. A. Compostos luminescentes em matrizes macroporosas de sílica obtidas por tratamento hidrotérmico a partir de vidro pyrex®. 182 f. Hybrid Sol-Gel-Derived Polymers: Applications of

SILVA, C.G.; WANG, W.; FARIA, J. L. “Photocatalytic and photochemical degradation of mono-, di- and tri-azo dyes in aqueous solution under UV irradiation”, Journal of Photochemistry and Photobiology A: Chemistry, 181, 314–324, 2006. Site: http://www.demar.eel.usp.br/compositos/Notas_aula/nanocompositos.pdf, Acesso em 08/09/2012, as 11:08 hs.

SU, C.; TSENG, C.M.; CHEN, L.F.; YOU, B.H.; HSU, B.C.; CHEN, S.S. Sol- hydrothermal preparation and photocatalysis of titanium dioxide. Thin Solid Films, 498, p. 259-265, 2006.

SUN, Z.; CHEN, Y.; KE, Q.; YANG, Y.; YUAN, J. Photocatalytic degradation of cationic azo dye by TiO2/bentonite nanocomposite. Journal of Photochemistry and

Photobiology A: Chemistry, v. 149, p. 169-174, 2002.

TANG, Z.; ZHANG, J.; CHENG, Z.; ZHANG, Z. Synthesis of nanosized rutile TiO2 powder at low temperature. Mater. Chem. Phys. 77, p. 314, 2002.

TELEKI, A.; PRATSINIS, S. E.; KALYANASUNDARAM, K.; GOUMAB, P. I. Sensing of organic vapors by flame-made TiO2 nanoparticles. Sensors and Actuators B, v. 119, p. 683-690, 2006.

TOMA, H. E. Interfaces e organizações da pesquisa no Brasil: da química à nanotecnologia. Quim. Nova, 28, S48-S51, 2005.

TONG, Tianzhong; ZHANG, Jinlong; TIAN, Baozhu; CHEN, Feng; HE, Dannong. Preparation of Fe3+ _{-doped TiO}2 _{catalysts by controlled hydrolysis of titanium}

alkoxide and study on their photocatalytic activity for methyl orange degradation.

Journal of Hazardous Materials, 155, p. 572-579, 2008.

WANG, Guohong. Hydrothermal synthesis and photocatalytic activity of nanocrystalline TiO2 powders in ethanol–water mixed solutions. Journal of

WARRIER, K. G. K.; JAIMY, K. B.; GHOSH, S. SANKAR, S. An aqueous sol- gelnsynthesis of chromium(III) doped mesoporous titanium dioxide for visible light photocatalysis. Materials Research Bulletin, v.46, n.6, p.914-921, 2011.

WU, J.; UCHIDA, S.; FUJISHIRO, Y.; YIN, S.; SATO, T. Synthesis and photocatalytic properties of HNbWO6/TiO2 and HNbWO6/Fe2O3 nanocomposites. Journal of

Photochemistry and Photobiology A: Chemistry, v. 128, p. 129-133, 1999.

XIE, Xiao-Lin; MAI, Yiu-Wing; ZHOU, Xing-Ping. Dispersion and alignment of carbon nanotubes in polymer matrix: A review. Materials Science and Engineering, v. 49. P. 89-112, 2005.

YOSHIKAWA, Susumu. Hydrothermal synthesis, characterization, photocatalytic activityand dye-sensitized solar cell performance of mesoporous anatase TiO2 nanopowders. Materials Research Bulletin, 43, p. 149–157, 2008.

YU, Jiaguo; YU, Jimmy C.; LEUNG, Mitch K. P.; HO, Wingkei; CHENG, Bei; ZHAO, Xiujian; ZHAO, Jincai. Effects of acidic and basic hydrolysis catalysts on the photocatalytic activity and microstructures of bimodal mesoporous titania. Journal of

Catalysis . 217, p. 69–78, 2003.

YUN, Jiaguo; WANG, Guohong; CHENG, Bei. Effects of microwave drying on the microstructure and photocatalytic activity of bimodal mesoporous TiO2 powders.

Journal of Physics and Chemistry of Solids. v. 71, p. 523–526, 2010.

Zhang H, Liu P, Liu X, Zhang S, Yao X, An T, et al. Fabrication of highly ordered TiO2 nanorod/nanotube adjacent arrays for photoelectrochemical applications.

Langmuir, 26:11226–32, 2010.

ZHANG, F.; WOLF, G. K.; WANG, X.; LIU, X. Surface properties of silver doped titanium oxide films. Surface and Coatings Technology, v. 148, p. 65-70, 2001. ZHU J.; JONGDAE K.; PENG H.; MARGRAVE J. L.; KHABASHESKU V. N.; BARRERA E. V. Improving the dispersion and integration os single-walled carbon nanotubes in epoxy composites through functionalization. Nanoletters, v. 3, n. 8, 1107-1113, 2008.

ZHUANG, W.; LIU, J.; ZHANG, J. H.; HU, B. X.; SHEN, J. Preparation, characterization, and properties of TiO2/PLA nanocomposites by in situ

In document A study of TRIM32 self-ubiquitination (sider 58-64)