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Doctoral Thesis
DOI
https://doi.org/10.11606/T.46.2011.tde-28032012-091521
Document
Author
Full name
Dulce Magalhães
E-mail
Institute/School/College
Knowledge Area
Date of Defense
Published
São Paulo, 2011
Supervisor
Committee
Matos, Jivaldo do Rosario (President)
Assunção, João Vicente de
Cosentino, Ivana Conte
Rothschild, Lilian
Serrano, Silvia Helena Pires
Title in Portuguese
Síntese, caracterização e aplicação de sílica mesoporosa esférica como adsorvente
Keywords in Portuguese
Compostos orgânicos voláteis
Cromatografia a gás
Pluronic P103 e P85 e P123
Rifampicina
Abstract in Portuguese
Novos tipos de sílicas mesoporosas esféricas (SMEs) com tamanho de partícula entre 3 e 10 µm foram sintetizadas utilizando os copolímeros tribloco EO17PO60EO17 (P103) ou EO26PO39EO26 (P85) como direcionadores de estrutura. As SMEs foram preparadas via um processo de síntese com duas etapas de tratamento hidrotérmico (TH) em forno convencional, utilizando o ortosilicato de tetraetila como fonte de sílica, os surfatantes P103 ou P85 como moldes em combinação com o co-surfatante brometo de cetiltrimetilamônio (CTAB) e o co-solvente etanol, sob condições ácidas. As SMEs obtidas foram caracterizadas por microscopia eletrônica de varredura (MEV) e medidas de adsorção/dessorção de N2. O volume e o tamanho do poro das SMEs podem ser aumentados com o aumento da temperatura do TH. O volume e o tamanho do poro (0,41 cm3g-1; 2,84 nm) da amostra sintetizada com P103 aumentaram (1,20 cm3g-1; 4,32 nm) quando a temperatura do TH aumentou de 80°C para 120°C na segunda etapa do TH. O aumento do volume e do tamanho de poro também pode ser obtido utilizando um único tratamento hidrotérmico, porém empregando 1,3,5-trimetilbenzeno (TMB) como agente dilatador de poros. O volume e o tamanho do poro (0,34 cm3g-1; 2,02 nm) da amostra sintetizada com P85 sem TMB aumentaram (0,37 cm3g-1; 2,51 nm) na amostra preparada com P85 e TMB. As características texturais e de superfície dos materiais obtidos com P103 e P85 foram comparadas com um material sintetizado em paralelo, nas mesmas condições experimentais, utilizando o copolímero EO20PO70EO20 (P123) como direcionador de estrutura e CTAB como co-surfatante. A SME sintetizada com P103 foi usada como adsorvente de compostos orgânicos voláteis (COVs) oriundos de misturas padrões. Os componentes da mistura padrão foram então removidos do adsorvente (sílica) por dessorção térmica e introduzidos em uma coluna cromatográfica para separação por cromatografia a gás (CG) e identificação por espectrometria de massa (EM). Esta SME foi também testada como adsorvente de uma amostra de ar coletada em uma rua com significativo fluxo de veículos. O ar foi coletado paralelamente na SME e num adsorvente comercial (Tenax TA/Carbotrap). Os compostos n-hexano, benzeno, tolueno e o-xileno, oriundos de emissões veiculares, foram encontrados em ambos adsorventes (sílica e Tenax TA/Carbotrap). O fármaco Rifampicina foi encapsulado numa SME sintetizada com P123/CTAB e na sílica SBA-15 (poros ordenados hexagonalmente). A encapsulação do fármaco (cerca de 30%) em ambas as sílicas foi confirmada pelos resultados de adsorção/dessorção de N2.
Title in English
Synthesis, characterization and application of spherical mesoporous silica as adsorbent
Keywords in English
Gas chromatography
Pluronic P103 and P85 and P123
Rifampicin
Volatile organic compounds
Abstract in English
New types of mesoporous silica spheres with particle diameter of 3 - 10 µm were synthesized by using a triblock copolymer EO17PO60EO17 (P103) or EO26PO39EO26 (P85) as templates. The microspheres were prepared via a two-step hydrothermal treatment (HT) in an oven by using tetraethoxysilane as silica source, the surfactants P103 or P85 as templates in combination with a cosurfactant cetyltrimethylammonium bromide (CTAB) and a cosolvent ethanol, under acidic conditions. The obtained silica spheres in both procedures were characterized by scanning electron microscopy (SEM) and N2 sorption technique. The volume and the pore size of the silica spheres can become greater by increasing the temperature of the HT. The volume and the pore size (0.41 cm3g-1; 2.84 nm) of the sample prepared with P103 became greater (1.20 cm3g-1; 4.32 nm) when the temperature of HT increased by 80°C to 120°C in the second step of the HT. The volume and the pore size can also be increased using 1,3,5-trimethylbenzene (TMB) as a swelling agent, instead of raising the temperature of the HT. The volume and the pore size (0.34 cm3g-1; 2.02 nm) of the sample prepared with P85 without TMB became greater (0.37 cm3g-1; 2.51 nm) in the sample prepared with P85 and TMB. The characteristics of textures and surfaces of the materials synthesized by using P103 or P85 were compared with a material prepared with the copolymer EO20PO70EO20 (P123) as template using the same experimental conditions. The silica microspheres synthesized with P103 were used as adsorbents for volatile organic compounds (VOCs) from standard mixtures. The compounds of the standard mixture were then removed from the adsorbent (silica) by thermal desorption and introduced into a chromatographic column for separation by gas chromatography (GC) and identification by mass spectrometry (MS). This material was also used as adsorbent of an air sample collected on a street with a significant flow of motor vehicles. The air was collected on the silica and on a commercial adsorbent (Tenax TA/Carbotrap) one by one. The compounds n-hexane, benzene, toluene and o-xylene, resulted from the emissions from vehicles, were found in both adsorbents (silica and Tenax TA/Carbotrap). The drug Rifampicin was encapsulated in the mesoporous spherical silica, prepared with P123/CTAB and in the silica SBA-15 (hexagonally ordered pores). The encapsulation of the drug (about 30%) in both the silica was confirmed by measurements of adsorption/desorption of N2
 
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Publishing Date
2012-05-16
 
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