Multifunctional mesoporous inorganic solids
Author(s)
Bibliographic Information
Multifunctional mesoporous inorganic solids
(NATO ASI series, ser.C . Mathematical and physical sciences ; v. 400)
Kluwer Academic Publishers, 1993
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Note
"Proceedings of the NATO Advanced Study Institute on Multifunctional Mesoporous Inorganic Solids, Sintra, Portugal, April 5-17, 1992"--T.p. verso
"Published in cooperation with NATO Scientific Affairs Division."
Includes bibliographical references index
Description and Table of Contents
Description
1. Introduction. There is much interest in the general subject of porous inorganic materials with respect to their use as sorbents or catalysts. Such inorganic solids may be microporous, mesoporous or macroporous according to the sizes of the pores within the solid. Often there is a range of pore sizes within any given solid and so there is special interest in the synthesis, characterisation and application of porous inorganic solids with well defined pores. Pores of diameter larger than 50 nm are generally termed macropores. Those with diameters of less than 2 nm are micropores and pores of intermediate size are called mesopores. Solids, which contain only mesopores, are correctly called mesoporous but very often there is a combination of different types of porosities within one given solid. The synthesis, characterisation and application of microporous solids is much more advanced than is the case with mesoporous substances. Moreover, the synthesis of crystalline mesoporous materials is one clear goal for the future but which has not been attained so far. Consequently, it is of interest to examine the current state of our knowledge of microporous materials and to examine how this may apply to mesoporous materials. Both catalytic and sorption processes could benefit from studies of mesoporous solids because the mesopores could permit diffusion of larger reactants or products than is the case in microporous materials. 2.
Table of Contents
I: The Measurement of Porosities. II: Porous Crystalline Materials. III: Pillared Layered Solids. IV: Sol-Gel Methods. V: Other Methods of Characterising Inorganic Materials. VI. Some Applications of Multifunctional Mesoporous Inorganic Materials. Subject Index.
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