S?ntese e caracteriza??o de pigmentos nanom?tricos encapsulados pelos m?todos dos precursores polim?ricos, hidrotermal de microondas e co-precipita??o associado ? qu?mica sol-gel convencional

Andrade, Jean Carlos Silva

10 February 2014

Submitted by Automa??o e Estat?stica (sst@bczm.ufrn.br) on 2016-01-20T20:35:40Z No. of bitstreams: 1 JeanCarlosSilvaAndrade_TESE.pdf: 5351227 bytes, checksum: 6baecb9ca1efd3ecbe1d465cdf5fbe9b (MD5) / Approved for entry into archive by Arlan Eloi Leite Silva (eloihistoriador@yahoo.com.br) on 2016-01-21T17:57:45Z (GMT) No. of bitstreams: 1 JeanCarlosSilvaAndrade_TESE.pdf: 5351227 bytes, checksum: 6baecb9ca1efd3ecbe1d465cdf5fbe9b (MD5) / Made available in DSpace on 2016-01-21T17:57:45Z (GMT). No. of bitstreams: 1 JeanCarlosSilvaAndrade_TESE.pdf: 5351227 bytes, checksum: 6baecb9ca1efd3ecbe1d465cdf5fbe9b (MD5) Previous issue date: 2014-02-10 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior - CAPES / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico - CNPq / A demanda por materiais com alta homogeneidade obtidos a temperaturas relativamente baixas vem alavancando a busca por processos qu?micos substituintes do m?todo cer?mico convencional. Esse trabalho tem como objetivo a obten??o de pigmentos nanom?tricos encapsulados (core-shell) a base de TiO2, dopados com ?ons de metais de transi??o (Fe, Co, Ni, Al) atrav?s de 3 (tr?s) m?todos de s?ntese: precursores polim?ricos (Pechini); hidrotermal de microondas; e co-precipita??o associado ? qu?mica sol-gel. O estudo foi motivado pela simplicidade, rapidez e baixo consumo de energia caracter?sticos desses m?todos. Os sistemas de custos s?o acess?veis, pois que permitem atingir um bom controle da microestrutura, aliada a elevada pureza, com controle estequiom?trico e de fases permitindo obter part?culas de tamanho nanom?trico. As propriedades f?sicas, qu?micas, morfol?gicas, ?pticas e estruturais dos materiais obtidos foram analisadas utilizando diferentes t?cnicas de caracteriza??o de materiais. Os p?s pigmentantes foram testados na descolora??o e degrada??o utilizando um fotoreator, atrav?s da solu??o do corante remazol amarelo ouro (RNL), a partir da filtra??o destas, resultando na separa??o da solu??o filtrante e dos pigmentos, para posterior realiza??o de medidas de UV-Vis. As diferentes temperaturas de calcina??o adotadas ap?s a obten??o dos p?s, nos diferentes m?todos foram: 400 ?C a 1000 ?C. Utilizando uma concentra??o fixa de 10% (Fe, Al, Ni, Co) em massa em rela??o ? massa do tit?nio, viabilizando tecnologicamente e economicamente o estudo. Atrav?s da t?cnica de microscopia eletr?nica de transmiss?o (MET) foi poss?vel analisar e confirmar a forma??o estrutural das part?culas de pigmentos nanom?tricos encapsulados, apresentando di?metro dos p?s de TiO2 entre 20 nm e 100 nm, e espessura da camada recoberta de Fe, Ni e Co entre 2 nm e 10 nm. O m?todo de s?ntese mais eficiente entre os estudados no trabalho foi o co-precipita??o associado ? qu?mica sol-gel, no qual foram obtidos os melhores resultados, sem a necessidade da obten??o de p?s pelo processo de calcina??o / The demand for materials with high consistency obtained at relatively low temperatures has been leveraging the search for chemical processes substituents of the conventional ceramic method. This paper aims to obtain nanosized pigments encapsulated (core-shell) the basis of TiO2 doped with transition metals (Fe, Co, Ni, Al) through three (3) methods of synthesis: polymeric precursors (Pechini); hydrothermal microwave, and co-precipitation associated with the sol-gel chemistry. The study was motivated by the simplicity, speed and low power consumption characteristic of these methods. Systems costs are affordable because they allow achieving good control of microstructure, combined with high purity, controlled stoichiometric phases and allowing to obtain particles of nanometer size. The physical, chemical, morphological, structural and optical properties of the materials obtained were analyzed using different techniques for materials characterization. The powder pigments were tested in discoloration and degradation using a photoreactor through the solution of Remazol yellow dye gold (NNI), such as filtration, resulting in a separation of solution and the filter pigments available for further UV-Vis measurements . Different calcination temperatures taken after obtaining the post, the different methods were: 400 ? C and 1000 ? C. Using a fixed concentration of 10% (Fe, Al, Ni, Co) mass relative to the mass of titanium technologically and economically enabling the study. By transmission electron microscopy (TEM) technique was possible to analyze and confirm the structural formation nanosized particles of encapsulated pigment, TiO2 having the diameter of 20 nm to 100 nm, and thickness of coated layer of Fe, Ni and Co between 2 nm and 10 nm. The method of synthesis more efficient has been studied in the work co-precipitation associated with sol-gel chemistry, in which the best results were achieved without the need for the obtainment of powders the calcination process

Tit?nia

Pigmento nanom?trico

?xidos met?lico

Co-precipita??o

Sol-gel e calcina??o

Estudo de titanatos nanoestruturados obtidos por tratamento hidrot?rmico de ?xido de tit?nio em meio alcalino / Studies on nanostructured titanates obtained by alkali hydrothermal treatment of titanium oxide

Morgado J?nior, Edisson

24 August 2007

Made available in DSpace on 2014-12-17T15:42:01Z (GMT). No. of bitstreams: 1 EdissonMJ.pdf: 6565731 bytes, checksum: 5d6fdd6db6fc25a30c6100d96fff1edc (MD5) Previous issue date: 2007-08-24 / TiTanate NanoTubes (TTNT) were synthesized by hydrothermal alkali treatment of TiO2 anatase followed by repeated washings with distinct degrees of proton exchange. TTNT samples with different sodium contents were characterized, as synthesized and after heattreatment (200-800?C), by X-ray diffraction, scanning and transmission electron microscopy, electron diffraction, thermal analysis, nitrogen adsorption and spectroscopic techniques like FTIR and UV-Vis diffuse reflectance. It was demonstrated that TTNTs consist of trititanate structure with general formula NaxH2−xTi3O7?nH2O, retaining interlayer water in its multiwalled structure. The removal of sodium reduces the amount of water and contracts the interlayer space leading, combined with other factors, to increased specific surface area and mesopore volume. TTNTs are mesoporous materials with two main contributions: pores smaller than 10 nm due to the inner volume of nanotubes and larger pores within 5-60 nm attributed to the interparticles space. Chemical composition and crystal structure of TTNTs do not depend on the average crystal size of the precursor TiO2-anatase, but this parameter affects significantly the morphology and textural properties of the nanostructured product. Such dependence has been rationalized using a dissolution-recrystallization mechanism, which takes into account the dissolution rate of the starting anatase and its influence on the relative rates of growth and curving of intermediate nanosheets. The thermal stability of TTNT is defined by the sodium content and in a lower extent by the crystallinity of the starting anatase. It has been demonstrated that after losing interlayer water within the range 100-200?C, TTNT transforms, at least partially, into an intermediate hexatitanate NaxH2−xTi6O13 still retaining the nanotubular morphology. Further thermal transformation of the nanostructured tri- and hexatitanates occurs at higher or lower temperature and follows different routes depending on the sodium content in the structure. At high sodium load (water washed samples) they sinter and grow towards bigger crystals of Na2Ti3O7 and Na2Ti6O13 in the form of rods and ribbons. In contrast, protonated TTNTs evolve to nanotubes of TiO2(B), which easily convert to anatase nanorods above 400?C. Besides hydroxyls and Lewis acidity typical of titanium oxides, TTNTs show a small contribution of protonic acidity capable of coordinating with pyridine at 150?C, which is lost after calcination and conversion into anatase. The isoeletric point of TTNTs was measured within the range 2.5-4.0, indicating behavior of a weak acid. Despite displaying semiconductor characteristics exhibiting typical absorption in the UV-Vis spectrum with estimated bandgap energy slightly higher than that of its TiO2 precursor, TTNTs showed very low performance in the photocatalytic degradation of cationic and anionic dyes. It was concluded that the basic reason resides in its layered titanate structure, which in comparison with the TiO2 form would be more prone to the so undesired electron-hole pair recombination, thus inhibiting the photooxidation reactions. After calcination of the protonated TTNT into anatase nanorods, the photocatalytic activity improved but not to the same level as that exhibited by its precursor anatase / Titanatos nanoestruturados, particularmente TiTanatos NanoTubulares (TTNT), foram sintetizados por tratamento hidrot?rmico alcalino de TiO2-anat?sio seguido de repetidas lavagens com diversos graus de troca prot?nica. Amostras de TTNT com diferentes teores de s?dio foram caracterizadas na forma de p? seco e ap?s calcina??o (200-800?C) por difra??o de raios-X, microscopia eletr?nica de varredura e transmiss?o, difra??o de el?trons, an?lise t?rmica, adsor??o de nitrog?nio e t?cnicas espectrosc?picas de infravermelho e de reflet?ncia difusa no UV-Vis?vel. Demonstrou-se que tais materiais de paredes multilamelares s?o trititanatos de f?rmula geral NaxH2−xTi3O7?nH2O, retendo ?gua entre as lamelas. A remo??o de s?dio da estrutura reduz a quantidade de ?gua contraindo o espa?o interlamelar levando, combinado a outros fatores, ao aumento da ?rea e do volume de poros espec?ficos. Os TTNTs s?o materiais mesoporosos com duas contribui??es principais: poros menores que 10 nm devido ao volume interno dos nanotubos e poros entre 5 e 60 nm devido aos espa?os interpart?cula. A composi??o qu?mica e a estrutura cristalina do TTNT n?o dependem do tamanho de cristalito do TiO2-anat?sio precursor, todavia este par?metro afeta significativamente a morfologia e as caracter?sticas texturais do produto nanoestruturado. Tal depend?ncia foi racionalizada atrav?s de um mecanismo de dissolu??o-recristaliza??o que leva em conta a velocidade de dissolu??o do TiO2 de partida e sua influ?ncia sobre a taxa de crescimento de nanofolhas intermedi?rias em rela??o ? taxa de seu curvamento a nanotubos. A estabilidade t?rmica do TTNT ? definida pelo teor de s?dio e em pequena extens?o pelo tipo de anat?sio de partida. Foi demonstrado que o TTNT ap?s perder a ?gua intercalada entre 100 e 200?C se transforma pelo menos parcialmente num hexatitanato NaxH2−xTi6O13 intermedi?rio ainda nanotubular. A transforma??o t?rmica do tri- e hexatitanato nanoestruturados ocorre em maior ou menor temperatura e segue diferentes rotas dependendo do teor de s?dio. No caso de alto s?dio sinterizam e crescem at? grandes cristais de Na2Ti3O7 e Na2Ti6O13 na forma de bast?es e fitas acima de 600?C. No caso da amostra protonizada evoluem para nanotubos de TiO2(B) que facilmente se convertem em nanobast?es de anat?sio acima de 400?C. Al?m de hidroxilas e acidez de Lewis t?picos dos ?xidos de tit?nio, os TTNTs apresentam uma pequena contribui??o de acidez prot?nica capaz de se coordenar com a piridina a 150?C, e que ? perdida ap?s sua calcina??o e transforma??o ? anat?sio. O ponto isoel?trico do TTNT variou dentro da faixa 2,5- 4,0, indicando o comportamento de um ?cido fraco. Apesar de se revelar um semicondutor exibindo banda de absor??o t?pica no espectro de UV-vis?vel com energia de bandgap ligeiramente superior ao do respectivo TiO2-anat?sio precursor, os TTNTs apresentaram baixo desempenho fotocatal?tico na degrada??o de corantes cati?nico e ani?nico. Concluiu-se que a causa fundamental reside em sua estrutura de titanato lamelar que, em rela??o ? forma TiO2, apresentaria maior probabilidade de recombina??o do par el?tron-lacuna (e-/h+), inibindo as rea??es de fotoxida??o. A transforma??o do TTNT prot?nico ? nanobast?es de anat?sio melhorou a atividade fotocatal?tica, por?m ainda sem atingir o mesmo desempenho do TiO2-anat?sio precursor

S?ntese hidrot?rmica alcalina

Materiais nanoestruturados

Transforma??o de fases

Titanatos lamelares

Tit?nia

Nanotubos

Mecanismo de dissolu??o-recristaliza??o

Alkaline hydrothermal synthesis

Nanostructured materials

Layered titanates

Titania

Nanotubes

Phase transformation

Dissolution-recrystallization mechanism