Etherification chemistry

Arguably the most challenging aspect for the preparation of 1 was construction of the unsymmetrically substituted sec-sec chiral bis(trifluoromethyl)benzylic ether functionality with careful control of the relative and absolute stereochemistry [21], The original chemistry route to ether intermediate 18 involved an unselective etherification of chiral alcohol 10 with racemic imidate 17 and separation of a nearly 1 1 mixture of diastereomers, as shown in Scheme 7.3. Carbon-oxygen single bond forming reactions leading directly to chiral acyclic sec-sec ethers are particularly rare since known reactions are typically nonstereospecific. While notable exceptions have surfaced [22], each method provides ethers with particular substitution patterns which are not broadly applicable. 

The original medicinal chemistry synthesis of ether 18 involved reaction of alcohol 10 with racemic imidate 17 in the presence of a catalytic amount of TfOH and furnished an approximately 1.1 1 mixture of 18 19 (Scheme 7.3) [1], We thought it worthwhile to reinvestigate this reaction with chiral imidate 67 in an effort to explore the diastereoselectivity of the etherification. 

V. Chemistry op the Etherification 1. Influence of the Colloidal Nature of the Cellulose... 

In carbohydrate chemistry, the preparation of ethers that are stable in the presence of acids, bases, and aqueous alkali is an important analytical and synthetic tool. The methods used for the etherification of hydroxyl groups51 generally employ reactions of unprotected sugars and glycosides with methyl, allyl, benzyl, triphenylmethyl, and alkylsilyl halides in the presence of a variety of aqueous and nonaqueous bases. 

Most chemists were more comfortable with speculations about movements of atoms than with flows of aether squirts. In particular, the idea of hydrogen atom mobility was to become a leading theme in late-nineteenth-century organic chemistry, based in the work of Williamson at midcentury. Williamson s investigations of etherification led him to a theory of the water "type" as well as to experimental proof that water is H20, not HO. Williamson clearly expressed the idea of chemical equilibrium as a balance between two sets of molecules in which some atoms or (uncharged) radicals may exist freely for short periods of time.43 In addition to its uncontestable central role in the "quiet revolution" of the 1850s,44 this was a paper that inspired both chemists and physicists to think about the "degree and kind of motion"45 of atoms within the molecule as well as the motion of the molecule as a whole. 

A. W. Williamson, "Results of a Research on Etherification" and "Suggestions for a Dynamics of Chemistry Derived from the Theory of Etherification," reprinted in Papers on Etherification and on the Constitution of Salts (Edinburgh Alembic Club Reprints, 1929), no. 16, 517, 1824. See J. R. Partington, A History of Chemistry, 580, 672. 

Although the Ir-catalyzed aUyhc substitution was developed only recently, several applications in the areas of medicinal and natural products chemistry have aheady been reported. In many syntheses the allylic substitution has been combined with a RCM reaction [71]. Examples not directed at natural products targets have aheady been described in Sections 9.4 and 9.5. It has also been mentioned that this strategy had previously been used in conjunction with aUyhc substitutions catalyzed by other transition metals (Figure 9.5). This was pioneered by P. A. Evans and colleagues, who used Rh-catalyzed allylic amination (compound A in Figure 9.5) [72] and etherification (compound B) [73], while Trost and coworkers demonstrated the power of this concept for Pd-catalyzed aUyhc alkylations (compound C) [74] and Alexakis et al. for Cu-catalyzed (compound D) aUyhc alkylations [75]. 

Here we report an overview of the different heterogeneously-catalyzed pathways designed for the selective conversion of carbohydrates. On the basis of these results, we shall try to determine the key parameters allowing a better control of the reaction selectivity. Water being commonly used as solvent in carbohydrate chemistry, we will also discuss the stability of solid catalysts in the aqueous phase. In this review, heterogeneously-catalyzed hydrolysis, dehydration, oxidation, esterification, and etherification of monosaccharides and polysaccharides are reported. 

Many reactions known in chemistry under special names, such as neutralization, esterification and etherification me dehydration reactions. See also Esterification. 

Williamson seems to have been the first to use the chemical term "dynamics with respect to some processes in one of the currently most widespread meanings (non-steady-state processes). The title of Williamson s work, in 1851, was simply Some considerations on chemistry dynamics exemplified by the etherification theory. 

Transition-metal-catalyzed synthesis of poly(arylene)s via carbon-carbon coupling reactions was started by Yamamoto et al. three decades ago [52,53] since then various carbon-carbon bond formation processes with transition-metal catalysts have been applied to polycondensation [54-57]. In recent years, Buchwald et al. and Hartwig et al. developed Pd-catalyzed amination and etherification of aromatic halides by using bulky, electron-rich phosphine ligands [58-60], and this chemistry has been applied to polycondensation for... 

The pioneer work in this field was carried out on polystyrene-supported acid catalysts [161]. Thereafter, several works on the use of sulfonic, strong acidic cation exchangers as acid catalysts were reported for alkylation, hydration, etherification, esterification, cleavage of ether bonds, dehydration, and aldol condensation [162,168-171], Besides, industrial applications of these materials were evaluated with reactions related to the chemistry of alkenes, that is, alkylation, isomerization, oligomerization, and acylation. [163,169], Also, Nation, an acid resin which has an acid strength equivalent to concentrated sulfuric acid, can be applied as an acid catalyst. It is used for the alkylation of aromatics with olefins in the liquid or gas phases and other reactions however, due to its low surface area, the Nation resin has relatively low catalytic activity in gas-phase reactions or liquid-phase processes where a nonpolar reactant or solvent is employed [166],... 

Sulfonic esters are frequently prepared as intermediates in carbohydrate chemistry, and their widespread use in synthetic work may be attributed to several factors adequate methods are available for sulfonylation in good yield, and sulfonyloxy groups exhibit high stability under the conditions used for acetalation, glycosidation, esterification, etherification, and mercaptalation. In many cases, the substituents introduced by these reactions may also be removed with-... 

There are two fundamental polymerization mechanisms. Classically, they have been differentiated as addition polymerization and condensation polymerization. In the addition process, no by-product is evolved, as in the polymerization of vinyl chloride (see below) whereas in the condensation process, just as in various condensation reactions (e.g., esterification, etherification, amidation, etc.) of organic chemistry, a low-molecular-weight by-product (e.g., H2O, HCl, etc.) is evolved. Polymers formed by addition polymerization do so by the successive addition of unsaturated monomer units in a chain reaction promoted by the active center. Therefore, addition polymerization is called chain polymerization. Similarly, condensation polymerization is referred to as step polymerization since the polymers in this case are formed by stepwise, intermolecular condensation of reactive groups. (The terms condensation and step are commonly used synonymously, as we shall do in this book, and so are the terms addition and chain. However, as it will be shown later in this section, these terms cannot always be used synonymously. In fact, the condensation-addition classification is primarily applicable to the composition or structure of polymers, whereas the step-chain classification applies to the mechanism of polymerization reactions.)... 

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