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Example Applications in Oxide Systems

As discussed earlier, EPR is ideally suited to the study of oxide surfaces, with particular reference to heterogeneous catalysis. This subject area has been reviewed [Pg.32]

Metal Oxide - Since metals are less electrophilic than silicon, metal oxide adsorbents show even stronger selectivity for polar molecules than do siliceous materials. The most commonly used metal oxide adsorbent is activated alumina, used primarily for gas drying. Occasionally, metal oxides find applications in specific chemisorption systems. For example, several processes are under development utilizing lime or limestone for removal of sulfur oxides from flue gases. Activated aluminas have surface areas in the range of 200 to 1,000 ftVft Average pore diameters range from about 30 to 80 A. [Pg.468]

As in other fields of nanosdence, the application of STM techniques to the study of ultrathin oxide layers has opened up a new era of oxide materials research. New emergent phenomena of structure, stoichiometry, and associated physical and chemical properties have been observed and new oxide phases, hitherto unknown in the form of bulk material, have been deteded in nanolayer form and have been elucidated with the help of the STM. Some of these oxide nanolayers are and will be of paramount interest to the field of advanced catalysis, as active and passive layers in catalytic model studies, on the one hand, and perhaps even as components in real nanocatalytic applications, on the other hand. We have illustrated with the help of prototypical examples the growth and the structural variety of oxide nanolayers on metal surfaces as seen from the perspective of the STM. The selection of the particular oxide systems presented here refleds in part their relevance in catalysis and is also related to our own scientific experience. [Pg.182]

An early application was to the pathway for conformational isomerization of molecules Ar3Z, with three aromatic rings on the same centre (Mislow, 1976). Typically the system is pyramidal (tetrahedral overall where there is a fourth substituent on Z), and the rings are close enough in space that they cannot rotate independently about the Z-Ar bond. Triphenylphosphine oxide, to take a specific example, crystallizes in a propeller conformation [4 Z = P=OJ which is chiral, with all three benzene rings rotated in the same sense from the relevant C-P-O plane. A study (Bye et al., 1982) of deformations from this geometry for more than 1000 related structures in various environments allowed a detailed description of the pathway for... [Pg.99]

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Application oxidation

Application oxide

Applications oxide systems

Applications system

Example applications

Oxidation systems

Oxidative systems

Oxide systems

Oxidized, applications

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