Synthesis and Characterization of Silica Nanotubes with Radially Oriented Mesopores

Yu, Yatao; Qiu, Huibin; Wu, Xiaowei; Li, Huachun; Li, Yongsheng; Sakamoto, Yasuhiro; Inoue, Yoshihisa; Sakamoto, Kazutami; Terasaki, Osamu; Che, Shunai

doi:10.1002/adfm.200700593

Cited by 64 publications

(50 citation statements)

References 53 publications

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“…AMS nanotubes with disordered radial mesopores have been prepared at 30 ° C by using various anionic surfactants, typically C 14 AlaS, as the template. [ 91 ] By investigating the initial surfactant gel and intermediate products in the formation of the nanotubes, a mechanism has been proposed, emphasizing the templating of the preformed bilayered tube-like gels of the surfactant for the mesoporous silica tubes. In another work, when C 14 AlaS is used as the template at the reaction temperature of 0 ° C, helical silica ribbons with disordered mesopores have been prepared, which in a similar manner come from templating of the ribbon-like gel of the anionic surfactant (Figure 7 f).…”

Section: Template Removal Strategy Of Ams For Obtaining Functional Mementioning

confidence: 99%

Organically Functionalized Mesoporous Silica by Co‐structure‐Directing Route

Gao

Che

2010

Adv Funct Materials

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This article provides a brief overview of functional mesoporous silica materials synthesized by the co‐structure‐directing route, which is distinct from conventional synthesis strategies. In these systems, organosilane serves as the co‐structure‐directing agent (CSDA), which provides critical interactions between the template and organic part of the organosilane to form mesostructures, thus retaining the organic groups on the pore surface after removal of the template by extraction. i) The formation of anionic‐surfactant‐templated mesoporous silicas (AMSs) has been achieved by the co‐structure‐directing route, which leads to a variety of mesostructures, porous properties and morphologies. ii) Other co‐structure‐directing systems for synthesizing mesoporous silicas have also been achieved, including systems using cationic surfactants and non‐surfactants, and systems using DNA for constructing nanofibers and DNA–silica liquid crystalline complexes. iii) Evidence for the regular arrangement of functional groups on the pore surface resulted from the co‐structure‐directing effect has been discussed. Also included is a brief description of the application, future requirements, and trends in the development of mesoporous materials by the co‐structure‐directing route.

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Section: Template Removal Strategy Of Ams For Obtaining Functional Mementioning

confidence: 99%

Organically Functionalized Mesoporous Silica by Co‐structure‐Directing Route

Gao

Che

2010

Adv Funct Materials

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“…[12][13][14][15][16][17][18] Also, the field effects, for example, gravitational, electric, magnetic, hydrodynamic, shear, and stress forces, [19] can influence the final morphology to a high degree. Until now a variety of mesoporous materials with particular micro-and macromorphologies, such as spheres, [20,21] rods, [22] fibers, [23] tubes, [24] thin films, [25] membranes, [26] monoliths, [27] and crystals, [28] have been prepared by adjusting the synthetic conditions. Nonetheless, some special techniques are necessary in these preparations, for instance solvent evaporation, [29] two-phase systems, [30,31] or special templates, such as a single-strand spider silk.…”

Section: Introductionmentioning

confidence: 99%

Functional Mesoporous Material Derived from 3D Net‐Linked SBA‐15

Zhou

Gao

et al. 2009

Chemistry A European J

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A novel, versatile functional mesoporous material with the structure of SBA-15 but a specific 3D net-linked morphology has been prepared by using a facile method. This material has been assessed for its ability to reduce the level of nitrosamines in tobacco smoke so that the actual effect of this material in the reduction of carcinogenic environmental pollutants in a complex chemical system can be verified. By adjusting the force field during the hydrolysis and condensation processes of tetramethyl orthosilicate (TMOS) in an aqueous reaction system, the SBA-15 silica, which has a special morphology in that it is long and fiberlike from a microscopic view but large and block-like from a macroscopic angle, has been successfully synthesized. Moreover, the synthetic product is no longer a powder but a block because of its specific 3D net-linked morphology, which enables the material not only to trap particles in smoke but also to potentially be applied as a device. To strengthen the adsorptive capability of this porous material, a dry-impregnation procedure was applied in which zirconia was coated on the silica wall without changing the morphology. As expected, this functional material shows a high activity in the adsorption of N'-nitrosonornicotine (NNN), a bulky tobacco-specific nitrosamine, in solution and of N-nitrosopyrrolidine (NPYR), a volatile nitrosamine, in the gas stream. Furthermore, this 3D net-linked SBA-15 material can efficiently decrease the amount of nitrosamines and total number of particles in mainstream smoke when it is tested as an additive in the filter of a cigarette, thus providing powerful protection for the environment and public health.

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“…Since Kuroda 5 and the company Mobil 6 reported the preparation of mesoporous silica, silica particles with various nanostructures including porous, hollow, and core-shell structures have been developed. In particular, silica nanotubes have recently attracted attention as these structures are known for biological compatibility, photoluminescence properties, low density, high-specific surface area, and the capability to incorporate materials; therefore, there are many potential applications of these structures as light materials, absorbing materials, separating agents, heat insulators, catalysts, biosensors, and nano-sized using the soft template method with chiral surfactants 19 , cationic 20,22 or anionic 21,22 surfactants, and hexagonal liquid crystals comprised of triblock copolymer surfactants or lipid nanotubes 23 as the template.…”

Section: Introductionmentioning

confidence: 99%