Catalyst single-site

The two most commonly used single-site catalysts for ADMET today are (1) Schrock s alkylidene catalysts of the type M(CHR )(NAr )(OR)2 where M = W or Mo, AC = 2, 6-C6H3-/-Pr2, R = CMe2Ph, and R = CMe(CF3)2 (14)7 and (2) Grubbs ruthenium-based catalyst, RuCl2(=CHPh)(PCy3)2 (12) where Cy = cyclohexyl.9 While both catalysts meet the requirements to be successful in ADMET, they are markedly different in their reactivity and in die results each can produce. 

In quest of new single-site catalysts for polymerizations of cyclic esters, a series of mononuclear yttrium(lll) complexes have been synthesized which are depicted in Scheme 221. ... 

Plastomers represent a major advancement for polyolefins. Their success allows polyolefins to have a continuum of products from amorphous EPR to thermoplastic PE and iPP. This development coincides with the advent of single-site catalysts these are necessary for copolymers of components of widely different reactivity such as ethylene and octene. Their rapid introduction into the mainstream polymer use indicates that this spectrum of properties and the inherent economy, stability and processibility of polyolefins are finding new applications to enter. 

PE and atactic PP lead to the recent explosion of interest in single-site catalysts. - ... 

Single Site Catalyst for Partial Oxidation Reaction ... 

By single-site catalysts we mean catalysts where the breaking and formation of chemical bonds occurs at isolated active centers whose chemical activity is dominated by the electronic properties of a single atomic species or of a small cluster of atoms that can act in an independent way with respect to others. 

Homogeneous catalysts are very often known as examples of single-site catalysts characterized by complete structural definition and (presumably) complete knowledge of the chemical processes occurring at their catalytic centers. It is a matter of fact that the homogeneous catalysts are molecular complexes constituted by an active core containing a single active atom (of-... 

True examples of single-site catalysts are enzymes, where active sites are made mainly by metalhc centers (mono- or polynuclear species) whose coordination sphere is completely defined by ligands [1-4]. The strength of enzymes is the combined effect of metal center activity with the specific behavior of metal coordination sphere hgands. These species play a key role, being optimized to create an environment suitable for (i) metal centers approaching and coordinating by reactants (ii) product removal from the catalytic centers at the end of the reaction in order to avoid further reactions. 

TS-1 is a material that perfectly fits the definition of single-site catalyst discussed in the previous Section. It is an active and selective catalyst in a number of low-temperature oxidation reactions with aqueous H2O2 as the oxidant. Such reactions include phenol hydroxylation [9,17], olefin epoxida-tion [9,10,14,17,40], alkane oxidation [11,17,20], oxidation of ammonia to hydroxylamine [14,17,18], cyclohexanone ammoximation [8,17,18,41], conversion of secondary amines to dialkylhydroxylamines [8,17], and conversion of secondary alcohols to ketones [9,17], (see Fig. 1). Few oxidation reactions with ozone and oxygen as oxidants have been investigated. 

Bordiga S, Damin A, Bonino F, Lamberti C (2005) Single Site Catalyst for Partial Oxidation Reaction TS-1 Case Stndy. 16 37-68 Bbttcher A, see Schmalz HG (2004) 7 157-180... 

Polymers manufactured via single site catalyst technologies, because of the unique chemical catalytic environment, exhibit a more controlled molecular weight distribution and tacticity than seen with Ziegler-Natta catalyst systems. 

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