Lewis acids properties

Many chiral metal complexes with Lewis acid properties have been developed and applied to the asymmetric Diels-Alder reaction. High enantioselectivity is, of course, one of the goals in the development of these catalysts. Enantioselectivity is not, however, the only factor important in their design. Other important considerations are ... 

Cations which are covalently attached to the allyl anion part by a cr-bond and have sufficient Lewis acid properties offer the broadest versatility and highest levels of stereocontrol, since the C—C bond-forming step can occur in a pericyclic process9 accompanied by allylic inversion. It is reasonable to assume the prior assembly of both reaction partners in an open-chain complex, in which usually the (F )-oxonium ion, avoiding allylic 1,3-strain10, is predominant. 

Essentially all allylsilanes (M = SiR3, Section D.l.3.3.3.5.) with the exception of fluorosil-iconates11 and most of the trialkyl(allyl)stannancs (Section D.l. 3.3.3.6.), which have only very weak Lewis acidic properties, require a strong Lewis acid to trigger the reaction with a carbonyl compound by the preceding formation of an x-oxycarbenium ion, which attacks the allylic compound in an ionic open-chain pathway. These Lewis acid catalyzed carbonyl additions offer new possibilities for the control of the simple and induced diastereoselectivity12. 

As far as investigated77, most reactions of the allyllithium-sparteine complexes with electrophiles proceed antarafacially, either as SE2 or anti-SE2 reactions. As a working hypothesis it is assumed that the bulky ligand obliterates the Lewis acid properties of the lithium cation. 

All these silicon reagents which activate metal surfaces are also Lewis acids, which can also contribute as such to the acceleration of any of the subsequently discussed reactions, because of their inherent Lewis acid properties. 

The types of ionic liquids shown in Figure 5.4 have been most extensively studied, especially ones based on chloroaluminate. Whilst these chloroaluminate materials also display useful Lewis acid properties they are highly air and moisture sensitive, which renders them relatively commercially unattractive. Newer ionic liquids containing C104 and NOa anions, for example, which are less air and moisture sensitive, are now being more widely studied, but these are less catalytically active. Other than lack of vapour pressure and catalytic properties there are several other features common to most ionic liquids that make them attractive reaction solvents. These include ... 

Various chemical species with Lewis acid properties are also effective in promoting the direct conversion of aldehydes into ethers by organosilicon hydrides. 

B,) Treatment of an organo- or a hydrido-nickel(II) compound with a Lewis acid. Organometallic compounds, such as alkylaluminum halides, which have Lewis acid properties, can also be used. 

Reactions involving bimetallic catalysts, either homo-dinuclear or hetero-bimetallic complexes, and chemzymes were highlighted by Steinhagen and Helmchen96c in 1996. Some examples are discussed in Chapter 2. Among these examples, Shibasaki s reports have been of particular significance.97 Shibasaki s catalyst is illustrated as 130, which consists of one central metal M1 (La+3, Ba+2, or A1+3), three other metal ions (M2)+ [(M2)+ can be Li+, Na+, or K+], and three bidentated ligands, such as (R)- or (iS )-BINOL. The catalyst exhibits both Lewis acidic properties because of the existence of central metal and the Lewis basic properties because of the presence of the outer metal ions. 

The Lewis acidic properties of chiral Cu(I) complexes have recently been exploited to augment the chemistry of the more developed Cu(II) Lewis acids. As a corollary, much less is known about the chemistry of Cu(I) Lewis acids. They have traditionally been categorized as soft Lewis acids, compared to the borderline-hard Cu(II) Lewis acids (1). 

The structural chemistry of the organotin halides is dominated by their Lewis acid properties and their propensity to form five- and six-coordinate complexes. Self-association may give oligomers or polymers in the solid state, which usually dissociate in solution. The structure of tricyclohexyltin chloride in the crystal is temperature-dependent. At 108 K, it has the form of a rod-like polymer with distorted trigonal-bipyramidal tin and Sn-Cl separations of 245.6(7) and 300.77(7) pm, but at 298 K, the structure is best regarded as consisting of near-tetrahedral discrete molecules.3... 

The solvent classifications used here are (1) solvents possessing both Lewis acid and Lewis base properties and a dielectric constant (D) > 25 (2) solvents possessing both Lewis acid and Lewis base properties and D < 25 (3) solvents possessing only Lewis acid properties and D> 25 (4) same as(3) but D < 25 (5) solvents possessing only Lewis base properties and D> 25 (6) same as(5)but D < 25 (7) solvents possessing negligible Lewis acid or base properties and D > 25 and (8) same as (7) but D < 25. 

Next to iodine there is also another class of neutral Lewis acids known. Tetracyanoethylene, dicyanoketene acetals and derivatives can catalyse reaction due to their tt-Lewis acid properties. They promoted the alcoholysis of epoxides [238], tetrahydropyranylation of alcohols [239], monothioacetahzation of acetals [240], and carbon-carbon bond formation of acetals [241,242] and imines [243] with silylated carbon nucleophiles. 

Zeolites and other mesoporous materials are excellent catalysts for industrial and laboratory applications. Favourable characteristics are their capacity to immobihze homogenous catalysts rendering them heterogeneous, their thermal stability, and the ease of separation from the reaction products and reuse in hquid- and gas-phase conditions. The pore size and Brpnsted and Lewis acidic properties are determinant for their use as catalyst in the Beckmann rearrangement. Recently, a review on the use of zeolites and mesoporous materials in the Beckmann rearrangement was published. ... 

Due to its Lewis acidic properties, the use of chloral (trichloroacetaldehyde) in the Beckmann rearrangement was investigated . When a variety of ketoximes is admixed with chloral hydrate and the mixture is heated at low pressure in nitrogen atmosphere, the Beckmann rearrangement afforded the corresponding amides in excellent yields (73-98%). The transformation occurs under neutral, relatively mild and solvent-free conditions. 

The catalytic effect is achieved through the weak Lewis acid properties of the metal ion as the active site in the metal chelate compound. The residual Lewis acid activity of aquo metal ions and incompletely coordinated metal ions in complexes and chelates in aqueous solution is actually very weak compared to that of the hydrogen ion on the other hand, metal ions and complexes are available in solution at high pH values, where the concentration of hydrogen ions is so low that their catalytic effect cannot be significant. 

When zeolite H-Y obtained by decationation of NH4-Y is heated further, water is irreversibly lost from the framework. The dehydroxylated zeolite Y displays Bronsted and Lewis acid properties. The mechanism for this process... 

Lewis Acid Properties of Zinc and Its Development to Phosphotriester Detoxifying Agents... 

This observation is not related to traces of base or acid from the silver salts used since control experiments mled out this possibility. It was known from the literature that the 5-exo-dig versus 6-endo-dig cyclization mode could depend on the nature of the carbonyl group,56 57 of the alkyne substituent,58 59 and of the nature60 61 and oxidation state62 of the metallic source used. Also, work from Yamamoto25 demonstrated the importance of both a- and Jt-Lewis acidity properties of silver(I) complexes. Therefore, depending on the silver salt used, two mechanistic pathways were proposed (pathways A and B, Scheme 5.15). 

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