Alcohol ruthenium catalysis

The ruthenium catalyst system, 14, shown in Fig. 3, also carries out ADMET condensation chemistry, albeit with higher concentrations being required to achieve reasonable reaction rates [32]. The possibility of intramolecular compl-exation with this catalyst influences the polymerization reaction, but nonetheless, ruthenium catalysis has proved to be a valuable contributor to overall condensation metathesis chemistry. Equally significant, these catalysts are tolerant to the presence of alcohol functionality [33] and are relatively easy to synthesize. For these reasons, ruthenium catalysis continues to be important in both ADMET and ring closing metathesis chemistry. 

Under the conditions of ruthenium catalysis, alcohols and allylic acetates couple to form enones,... 

The 5-endo and 6-endo cyclizations of a,a>-alkynols leading to dihydrofurans and dihydropyrans have been achieved with molybdenum and tungsten catalysis [6]. Transition-metal vinylidene intermediates have been claimed to be involved in these cycloisomerizations [7]. Related cyclizations of bis-homo-propargyl alcohols were recently developed using ruthenium catalysis as shown in Eq. (3) [8]. In the presence of the sodium salt of N-hydroxysuccinimide 9,... 

Scheme 8.53 Photoactivated DKR of alcohols through enzymatic and ruthenium catalysis.

There has been considerable recent interest in the reductions of [Fe(CN)6]. The electron exchange with A -propyl-l,4-dihydronicotinamide is catalyzed by alkali metal ions. The increase in reaction rate is attributed to the polarizability of M and the observed linear free energy relationship is discussed. An outer-sphere mechanism is postulated in the oxidation of phenothiazines. A free radical mechanism involving the alcohol anion is invoked in the reaction of 1-and 2-propanol in aqueous alkaline media, the kinetic order being unity for [Fe(CN)6], OH, and alcohol concentrations. Catalysis by metal ions has also been observed in the presence of copper(II) and ruthenium(III) complexes. In the oxidation of a-hydroxypropionic acid in alkaline media,a Cu(II)-ligand complex is formed which is oxidized slowly to a copper(III) species. Alkaline ferricyanide oxidizes butanol, the process being catalyzed by chlororuthenium complexes.The rate law is consistent with oxidation of the alcohol by the Ru(III) followed by reoxidation of the catalyst by [Fe(CN)6]. The rate law is of the form ... 

Although the scope of this book chapter encompasses Ru-based catalysts, recent reports have also proceeded in a more biologically relevant direction with the implementation of environmentally benign, inexpensive, and more abundant metals, such as iron and cobalt, for dehydrogenation processes of alcohols [18-20, 75] and formic acid [73-75, 211-213]. In summary, the reports discussed in this review chapter have demonstrated the capabilities of ruthenium catalysis with respect to dehydrogenation, where alcohols still require further development for sufficient hydrogen yields but formic acid is significantly closer to a renewable and reversible solution. 

Montagut-Romans A, Boulven M, Lemaire M, Popowycz F. Efficient C-3 reductive alkylation of 4-hydroxycoumarin by dehydrogenative oxidation of benzybc alcohols through ruthenium catalysis. New J Chem. 2014 38 1794-1801. 

Chiral amino alcohols are common structures in drug molecules for example, y-secondaiy aminoalcohols are key intermediates in the synthesis of several pharmaceuticals, examples of which are shown in Scheme 14.12. Zhang has shown that Rh-DuanPhos catalysts can be used to synthesise these key intermediates directly via asymmetric hydrogenation of the p-secondary amino ketone. Application to the synthesis of the antidepressant duloxetine is shown in Scheme 14.12. It should be noted that, to date, ruthenium catalysis has not been successfully applied to the reduction of secondary amino substrates a tertiary amino group is required resulting in a less efficient synthesis requiring extra S3mthetic steps. ... 

Techniques for attaching such ruthenium electrocatalysts to the electrode surface, and thereby realizing some of the advantages of the modified electrode devices, have been developed.512-521 The electrocatalytic activity of these films have been evaluated and some preparative scale experiments performed. The modified electrodes are active and selective catalysts for oxidation of alcohols.5 6-521 However, the kinetics of the catalysis is markedly slower with films compared to bulk solution. This is a consequence of the slowness of the access to highest oxidation states of the complex and of the chemical reactions coupled with the electron transfer in films. In compensation, the stability of catalysts is dramatically improved in films, especially with complexes sensitive to bpy ligand loss like [Ru(bpy)2(0)2]2 + 51, 519 521... 

High chemoselectivity is observed in this ruthenium-catalyzed isomerization of allylic alcohols. Simple primary and secondary alcohols and isolated double bonds are not affected by these catalysts. Furthermore, free hydroxy group is essential for this catalysis. The reaction of l-acetoxycyclododec-2-ene-4-ol furnished 4-acetoxycyclododecanone in high yield (Scheme 14).37... 

Ruthenium complexes B are stable in the presence of alcohols, amines, or water, even at 60 °C. Olefin metathesis can be realized even in water as solvent, either using ruthenium carbene complexes with water-soluble phosphine ligands [815], or in emulsions. These complexes are also stable in air [584]. No olefination of aldehydes, ketones, or derivatives of carboxylic acids has been observed [582]. During catalysis of olefin metathesis replacement of one phosphine ligand by an olefin can occur [598,809]. 

Pahnans et al. prepared 5 by the reaction of [RuCl2(p-cymene)]2 and 2-phenyl-2-aminopropionamide in the presence of potassium carbonate. They used 5 in an iterative tandem catalysis for the synthesis of chiral oligoesters. The enzymatic ring opening of 6-methyl-e-caprolactone was combined with ruthenium-catalyzed alcohol racemization to produce optically active oligomers of 6-methyl-e-capro-lactone [23] (Scheme 1.17). 

Highly reactive organic vinylidene and allenylidene species can be stabilized upon coordination to a metal center [1]. In 1979, Bruce et al. [2] reported the first ruthenium vinylidene complex from phenylacetylene and [RuCpCl(PPh3)2] in the presence of NH4PF6. Following this report, various mthenium vinylidene complexes have been isolated and their physical and chemical properties have been extensively elucidated [3]. As the a-carbon of ruthenium vinylidenes and the a and y-carbon of ruthenium allenylidenes are electrophilic in nature [4], the direct formation of ruthenium vinylidene and ruthenium allenylidene species, respectively, from terminal alkynes and propargylic alcohols provides easy access to numerous catalytic reactions since nucleophilic addition at these carbons is a viable route for new catalysis (Scheme 6.1). 

Mention must also be made of the work of J.F. Knifton from Texaco who has demonstrated the use of ruthenium melt catalysis for the production of a wide range of commodity chemicals (alcohols, acids and esters) and fuels (j ). 

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