Template Synthesis and Mesostructural characterization of Ordered Mesoporous Silica, Titania and Carbon Materials

Kao, Li-Heng

03 January 2008

Template synthesis and mesostructural characterization of ordered mesoporous silica, titania and carbon materials have been systematically investigated in this study. In order to obtain a better understanding of the template-precursor relationship, there are two templates adopted in this research. One is the ¡§liquid crystal template (LCT)¡¨, composed of surfactants via self-assembly pathway; the other is the ¡§ordered silica spheres template¡¨, composed of monodispersed SiO2 spheres (~40 nm) via gravity sedimentation. This work was carried out in four related directions: (1) Synthesis and functionalization of ordered mesoporous silicate (MCM-41 and MCM-48) via cationic surfactant template; (2) Using anionic surfactant template-assisted via urea treatment to control the morphology of the TiO2; (3) Synthesis of ordered mesoporous anatase TiO2 via cationic surfactant template; (4) Synthesis of ordered mesoporous carbon from mesophase pitch solution via silica spheres template. Mesoporous silica materials MCM-41 and MCM-48 have been synthesized and identified. The MCM-41 has a hexagonal phase (p6m) with surface area of 1006.90 m2/g and pore size of 37.65 Å, The MCM-48 has cubic phase ( ) with surface area of 1093.34 m2/g and pore size of 29.20 Å. The calcined MCM-41was rehydrated by heating in water and functionalized with 3-amino propyltrimethoxysilane; this functionalized mesoporous silica is targeted as a template of metal oxides, such as TiO2. appears the same tendency of parent MCM-41 in the N2 sorption isotherm measurements. Nanocrystalline TiO2 rods and hollow-tubes with an engraved pattern on the surface have been prepared by the anionic template-assisted sol-gel synthesis via urea treatment and under hydrothermal condition. X-ray diffractometry (XRD) results indicate that these nanocrystallines consist predominantly of anatase TiO2, with minor amounts of rutile and brookite. The crystallographic facetting found from SEM and TEM further reveals the polymorphic nature of the nanocrystalline TiO2 thus prepared. A ¡§reverse micelle¡¨ formation mechanism taking into account the hydrothermal temperature, the pH effect of the sol-gel system, the isoelectric point, the formation of micelles, and the electrostatic interaction between the anionic surfactant and the growing TiO2 particulates is proposed to illustrate the competition between the physical micelle assembly of the ionic surfactants and the chemical hydrolysis and condensation reactions of the Ti precursors. Ordered mesoporous TiO2 materials with an anatase framework have been synthesized by using a cationic surfactant template and soluble peroxytitanates as Ti precursor through an S+I− self-assembly pathway. The low-angle X-ray diffraction (XRD) pattern of the as-prepared mesoporous TiO2 materials indicates a hexagonal mesostructure. XRD and TEM results and N2 sorption isotherms measurements indicate the calcined mesoporous TiO2 possesses an anatase crystalline framework having a maximum pore size of 6.9 nm and a maximum BET specific surface area of 284 m2/g. This ordered mesoporous TiO2 also demonstrates a high photocatalytic activity for degradation of methylene blue under ultraviolet irradiation. Under a lower carbonization temperature and with a mesophase pitch solution as the carbon precursor, ordered mesoporous carbon thick films with 35-nm pore size have been synthesized using SiO2 spheres as the template. The pore size of the mesoporous carbon thus fabricated was the smallest one ever reported using silica templates. SEM and TEM patterns show a discernible morphology of an ordered cubic close-packing of the mesopores interconnected via holes of 6 nm in diameter. From this study, the template synthesis has been proven to be an effective method to fabricate mesoporous silica, polymorphic titania, ordered mesoporous TiO2, and ordered mesoporous carbon materials. Further utilization of this template synthesis is expected to offer a variety of porous networks with a wide range of pore sizes, well-defined morphologies on controllable length scales, and various chemical functionalities to match the needs of different applications.

ordered mesoporous silica

template method

mesostructure

ordered mesoporous carbon

ordered mesoporous titania

Cristaux liquides, empreinte pour la préparation de matériaux mésoporeux organisés : application à la synthèse d'oxyde de titane nanocristallin / Liquid crystals, template for the preparation of ordered mesoporous materials : application to the synthesis of nanocrystalline titania

Zimny, Kévin

12 November 2010

Ce travail est consacré à la préparation de matériaux mésoporeux à partir de cristaux liquides formés avec des tensioactifs fluorés selon le mécanisme transcriptif LCT. Les paramètres de synthèse ont été optimisés pour la préparation de silices mésostructurées à partir de la phase hexagonale du système eau/C8F17C2H4(OCH2CH2)9OH. Les résultats montrent une corrélation entre le diamètre des pores des matériaux et les diamètres hydrophobes mesurés dans les cristaux liquides. L'incorporation de TiO2 dans une matrice silicatée selon la méthode de coprécipitation a été réalisée en utilisant soit des micelles (mécanisme d'auto-assemblage coopératif CTM), soit la phase hexagonale du système C8F17C2H4(OCH2CH2)9OH/eau (mécanisme transcriptif LCT). Dans les deux cas, l'incorporation de titane conduit à une perte de la structure et à une diminution de la surface spécifique. L'utilisation du mécanisme CTM favorise la formation de TiO2 anatase en surface du matériau, tandis que pour le mécanisme LCT, la substitution du silicium par le titane au coeur du matériau a été mise en évidence. Des films minces mésostructurés à base de TiO2 ont été réalisés à partir de la méthode EISA. Les analyses par diffraction des rayons X à incidence rasante couplées à des mesures de réflectivité ont permis de mettre en évidence la structure des films et de déterminer les épaisseurs des couches qui constituent les films. Enfin, une méthode originale de synthèse de matériaux mésoporeux organisés à base de TiO2 a été développée. La précipitation de TiO2 dans la mésophase hybride est déclenchée à l'aide d'un traitement par NH3 (g). La structure des matériaux est conservée après l'étape de calcination laquelle permet de cristalliser TiO2 en phase anatase. L'activité photocatalytique de ces matériaux a ensuite été testée sur la réaction de photodégradation du méthylorange / This work deals with the preparation of mesoporous materials from fluorinated liquid crystals via the LCT mechanism. Synthesis parameters have been optimized for the preparation of ordered mesoporous silica with the hexagonal H1 phase of water/C8F17C2H4(OCH2CH2)9OH system. Results show a correlation between pore diameters of materials and hydrophobic diameters measured in liquid crystals. According to the coprecipitation method, incorporation of TiO2 in a silica matrix, synthesized using micelles (via the cooperative templating mechanism CTM) or the hexagonal phase of C8F17C2H4(OCH2CH2)9OH/water system (via liquid crystal templating mechanism LCT). Both pathways lead to a loss of mesopore ordering and a decrease of the specific surface area when titania content increases. If materials are prepared via CTM mechanism TiO2 is present on the surface whereas TiO2 is in the bulk when LCT mechanism is used. Mesoporous thin films have been prepared via EISA method. Grazing incidence small angle X-Ray scattering and reflectivity analysis have been used to define the structure of films and the thickness of the different layers. Finally an original method has been developed for the preparation of ordered titania mesoporous materials. Precipitation of titania in the hybrid mesophase is activated by a NH3 treatment. The structure is preserved after calcination step which allow the formation of TiO2 anatase. Photocatalytic activity of these materials has been tested on the photodegradation of methylorange

Tensioactif fluoré non ionique

Cristaux liquides

Micelles

Silices mésoporeuses organisées

Titane mésoporeux organisé

Titanosilicates

Films minces

Nonionic fluorinated surfactant

Liquid crystals

Micelles

Ordered mesoporous silica

Ordered mesoporous titania

Titanosilicates

Thin films