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Mesoporous material hexagonal

Titanium containing hexagonal mesoporous materials were synthesized by the modified hydrothermal synthesis method. The synthesized Ti-MCM-41 has hi y ordered hexa rud structure. Ti-MCM-41 was transformed into TS-l/MCM-41 by using the dry gel conversion process. For the synthesis of Ti-MCM-41 with TS-1(TS-1/MCM-41) structure TPAOH was used as the template. The synthesized TS-l/MCM-41 has hexagonal mesopores when the DGC process was carried out for less than 3 6 h. The catalytic activity of synthesized TS-l/MCM-41 catalysts was measured by the epoxidation of 1-hexene and cyclohexene. For the comparison of the catalytic activity, TS-1 and Ti-MCM-41 samples were also applied to the epoxidation reaction under the same reaction conditions. Both the conversion of olefins and selectivity to epoxide over TS-l/MCM-41 are found hi er flian those of other catalysts. [Pg.792]

Since the discovery by researchers at Mobil of a new family of crystalline mesoporous materials (1), a large effort has been expended on synthesis, characterization, and catalytic evalrration (2). MCM-41 is a one-dimerrsiorral, hexagonal structure. MCM-48 is a cubic structine with two, norrintersecting pore systems (3). MCM-50 is a layered stractme with silica sheets between the layers (4). Many scientists also looked into other mesoporous materials, of note the HMS (Hexagonal Molecular Sieve) family (5) and SBA-15 (acronym derived from Santa Barbara University) (6), bnt to date few materials have been both catalytically significant and inexpensive to synthesize. [Pg.367]

Figure 41.4 shows a typical XRD (X-Ray Diffraction) pattern of TUD-1, along with a TEM image (12). Similar to other mesoporous materials, TUD-1 has a broad peak at low 20. However, it has a broad background peak, commonly called an amorphous halo, and lacks any secondary peaks that are evident for example in the hexagonal MCM-41 and cubic MCM-48 structures. The TEM shows that the pores have no apparent periodicity. In this example the pore diameter is about 5 nm. [Pg.370]

Time-resolved in situ Small Angle Neutron Scattering (SANS) investigations have provided direct experimental evidence for the initial steps in the formation of the SBA-15 mesoporous material, prepared using the non-ionic tri-block copolymer Pluronic 123 and TEOS as silica precursor. Upon time, three steps take place during the cooperative self-assembly of the Pluronic micelles and the silica species. First, the hydrolysis of TEOS is completed, without modifications of the Pluronic spherical micelles. Then, when silica species begin to interact with the micelles, a transformation from spherical to cylindrical micelles takes place before the precipitation of the ordered SBA-15 material. Lastly, the precipitation occurs and hybrid cylindrical micelles assemble into the two-dimensional hexagonal structure of SBA-15. [Pg.53]

The reason why the hybrid micelles evolve from sphere to cylinder is not yet completely understood, but it results from the fact that when silica species are adsorbed onto the surface of the micelles, the average curvature of the micelles is decreasing [9], Polymerisation of silica species by condensation leads to precipitation of the ordered hexagonal mesoporous material. [Pg.58]

The most widely studied member of the M41S family is hexagonal MCM-41, which was first prepared by the I S+ liquid-crystal approach (168, 169). A charged surfactant like CTAB produces well-ordered mesoporous materials having ID... [Pg.251]

Since their relatively recent discovery, ordered mesoporous materials have attracted much interest because of their high surface area and uniform distribution of mesopore diameters. Because of its hexagonal array of uniform one-dimensional mesopores, varying in diameter from 1.5 to 10 nm, MCM41 is a potentially interesting catalyst for converting large molecules of nondistillable feeds to fuels and other products [103]. [Pg.245]

In previous literature, the type B hysteresis was ascribed to a lamellar-like structure that commonly observed in the pillared materials.[13,14] Here its existence in our mesoporous materials is associated with some internal defects in the channels. To further understand such hysteresis behavior, we compared the microtomed ultra-thin sections TEM micrographs of these two samples. In Fig. 2A, B, we show the typical parallel channels of MCM-41 and the well-ordered hexagonal mesoporous in pure silica sample(I). However in Fig. 2 C, D, one can obviously find the aluminosilicate(II) possessing the normal well-aligned MCM-41 nanochannels with extensive voids interspersed. The white void parts were attributed to the structural defects. These structural defects are not the lamellar form but the irregularly shaped defects. The size of the defects is not uniform and distributes between 5.0-30.0 nm. nanometers. Therefore, these aluminosilicate mesoporous materials were composed of structural defects-within-well-ordered hexagonal nanochannels matrix. [Pg.18]

The introduction of organic groups within the framework of the mesoporous material has improved the periodicity of the pore-arrangement with the symmetries. Figure 4 shows the XRD patterns of the three types of mesoporous materials with 2D-hexagonal symmetry (p6mm). [Pg.159]

Figure 5. SEM photographs of hybrid mesoporous materials with (a) 2D- and (b) 3D- hexagonal symmetric. Figure 5. SEM photographs of hybrid mesoporous materials with (a) 2D- and (b) 3D- hexagonal symmetric.
The AlSBA mesoporous molecular sieves can be obtained easily by direct synthesis. These novel mesoporous materials retain the hexagonal order and physical properties of AlMCM-41... [Pg.217]

MCM-41 is most extensively studied member of the M41S family because of its hexagonal array of unidimensional pore architecture. In addition to catalysis, MCM-41 type mesoporous materials are increasingly being explored for a variety of different applications, such as support, as sensors / carriers, surface modification etc. [Pg.283]


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See also in sourсe #XX -- [ Pg.425 ]




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