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Carbonylation catalysis

Asymmetric Synthesis by Homogeneous Catalysis Carbonylation Processes by Homogeneous Catalysis Coordination Organometalhc Chemistry Principles Electronic Stmcture of Clusters Hydride Complexes of the Transition Metals Hydrides Sohd State Transition Metal Complexes Organic Synthesis using Transition Metal Complexes Containing 7t-Bonded Ligands Oxidation... [Pg.3543]

Keywords Asymmetric catalysis Carbonyl compounds Copper Enantioselectivity Regioselectivity Silanes... [Pg.207]

The regioselectivity benefits from the increased polarisation of the alkene moiety, reflected in the increased difference in the orbital coefficients on carbon 1 and 2. The increase in endo-exo selectivity is a result of an increased secondary orbital interaction that can be attributed to the increased orbital coefficient on the carbonyl carbon ". Also increased dipolar interactions, as a result of an increased polarisation, will contribute. Interestingly, Yamamoto has demonstrated that by usirg a very bulky catalyst the endo-pathway can be blocked and an excess of exo product can be obtained The increased di as tereo facial selectivity has been attributed to a more compact transition state for the catalysed reaction as a result of more efficient primary and secondary orbital interactions as well as conformational changes in the complexed dienophile" . Calculations show that, with the polarisation of the dienophile, the extent of asynchronicity in the activated complex increases . Some authors even report a zwitteriorric character of the activated complex of the Lewis-acid catalysed reaction " . Currently, Lewis-acid catalysis of Diels-Alder reactions is everyday practice in synthetic organic chemistry. [Pg.12]

Finally, if there could be a way in which in water selective ri Jt-coordination to the carbonyl group of an a,P-imsatLirated ketone can be achieved, this would be a breakthrough, since it would subject monodentate reactants to catalysis by hard Lewis acids ". ... [Pg.169]

A regioselective aldol condensation described by Biichi succeeds for sterical reasons (G. Biichi, 1968). If one treats the diaidehyde given below with acid, both possible enols are probably formed in a reversible reaaion. Only compound A, however, is found as a product, since in B the interaction between the enol and ester groups which are in the same plane hinders the cyclization. BOchi used acid catalysis instead of the usual base catalysis. This is often advisable, when sterical hindrance may be important. It works, because the addition of a proton or a Lewis acid to a carbonyl oxygen acidifies the neighbouring CH-bonds. [Pg.55]

The benzoic acid derivative 457 is formed by the carbonylation of iodoben-zene in aqueous DMF (1 1) without using a phosphine ligand at room temperature and 1 atm[311]. As optimum conditions for the technical synthesis of the anthranilic acid derivative 458, it has been found that A-acetyl protection, which has a chelating effect, is important[312]. Phase-transfer catalysis is combined with the Pd-catalyzed carbonylation of halides[3l3]. Carbonylation of 1,1-dibromoalkenes in the presence of a phase-transfer catalyst gives the gem-inal dicarboxylic acid 459. Use of a polar solvent is important[314]. Interestingly, addition of trimethylsilyl chloride (2 equiv.) increased yield of the lactone 460 remarkabiy[3l5]. Formate esters as a CO source and NaOR are used for the carbonylation of aryl iodides under a nitrogen atmosphere without using CO[316]. Chlorobenzene coordinated by Cr(CO)j is carbonylated with ethyl formate[3l7]. [Pg.190]

Carbonyiation of butadiene gives two different products depending on the catalytic species. When PdCl is used in ethanol, ethyl 3-pentenoate (91) is obtained[87,88]. Further carbonyiation of 3-pentenoate catalyzed by cobalt carbonyl affords adipate 92[89], 3-Pentenoate is also obtained in the presence of acid. On the other hand, with catalysis by Pd(OAc)2 and Ph3P, methyl 3,8-nonadienoate (93) is obtained by dimerization-carbonylation[90,91]. The presence of chloride ion firmly attached to Pd makes the difference. The reaction is slow, and higher catalytic activity was observed by using Pd(OAc) , (/-Pr) ,P, and maleic anhydride[92]. Carbonyiation of isoprcne with either PdCi or Pd(OAc)2 and Ph,P gives only the 4-methyl-3-pentenoate 94[93]. [Pg.437]

Many of the most interesting and useful reactions of aldehydes and ketones involve trans formation of the initial product of nucleophilic addition to some other substance under the reaction conditions An example is the reaction of aldehydes with alcohols under con ditions of acid catalysis The expected product of nucleophilic addition of the alcohol to the carbonyl group is called a hemiacetal The product actually isolated however cor responds to reaction of one mole of the aldehyde with two moles of alcohol to give gem mal diethers known as acetals... [Pg.720]

Under conditions of acid catalysis the nucleophilic addition step follows protonation of the carbonyl oxygen Protonation increases the carbocat ion character of a carbonyl group and makes it more electrophilic... [Pg.742]

The point was made earlier (Section 5 9) that alcohols require acid catalysis in order to undergo dehydration to alkenes Thus it may seem strange that aldol addition products can be dehydrated in base This is another example of the way in which the enhanced acidity of protons at the a carbon atom affects the reactions of carbonyl com pounds Elimination may take place in a concerted E2 fashion or it may be stepwise and proceed through an enolate ion... [Pg.772]

The sonochemistry of solutes dissolved in organic Hquids also remains largely unexplored. The sonochemistry of metal carbonyl compounds is an exception (57). Detailed studies of these systems led to important mechanistic understandings of the nature of sonochemistry. A variety of unusual reactivity patterns have been observed during ultrasonic irradiation, including multiple ligand dissociation, novel metal cluster formation, and the initiation of homogeneous catalysis at low ambient temperature (57). [Pg.262]

Chromium compounds decompose primary and secondary hydroperoxides to the corresponding carbonyl compounds, both homogeneously and heterogeneously (187—191). The mechanism of chromium catalyst interaction with hydroperoxides may involve generation of hexavalent chromium in the form of an alkyl chromate, which decomposes heterolyticaHy to give ketone (192). The oxidation of alcohol intermediates may also proceed through chromate ester intermediates (193). Therefore, chromium catalysis tends to increase the ketone alcohol ratio in the product (194,195). [Pg.343]

Acetylene is condensed with carbonyl compounds to give a wide variety of products, some of which are the substrates for the preparation of families of derivatives. The most commercially significant reaction is the condensation of acetylene with formaldehyde. The reaction does not proceed well with base catalysis which works well with other carbonyl compounds and it was discovered by Reppe (33) that acetylene under pressure (304 kPa (3 atm), or above) reacts smoothly with formaldehyde at 100°C in the presence of a copper acetyUde complex catalyst. The reaction can be controlled to give either propargyl alcohol or butynediol (see Acetylene-DERIVED chemicals). 2-Butyne-l,4-diol, its hydroxyethyl ethers, and propargyl alcohol are used as corrosion inhibitors. 2,3-Dibromo-2-butene-l,4-diol is used as a flame retardant in polyurethane and other polymer systems (see Bromine compounds Elame retardants). [Pg.393]

The main uses of metal carbonyls are in the areas of catalysis and organic synthesis. The Reppe synthesis and 0x0 process are both of enormous industrial importance. [Pg.70]

Positionalisomeri tion occurs most often duting partial hydrogenation of unsaturated fatty acids it also occurs ia strongly basic or acidic solution and by catalysis with metal hydrides or organometaUic carbonyl complexes. Concentrated sulfuric or 70% perchloric acid treatment of oleic acid at 85°C produces y-stearolactone from a series of double-bond isomerizations, hydration, and dehydration steps (57). [Pg.86]

There are only a few weU-documented examples of catalysis by metal clusters, and not many are to be expected as most metal clusters are fragile and fragment to give metal complexes or aggregate to give metal under reaction conditions (39). However, the metal carbonyl clusters are conceptually important because they form a bridge between catalysts commonly used in solution, ie, transition-metal complexes with single metal atoms, and catalysts commonly used on surfaces, ie, small metal particles or clusters. [Pg.169]

Polymer-supported catalysts incorporating organometaUic complexes also behave in much the same way as their soluble analogues (28). Extensive research has been done in attempts to develop supported rhodium complex catalysts for olefin hydroformylation and methanol carbonylation, but the effort has not been commercially successful. The difficulty is that the polymer-supported catalysts are not sufftciendy stable the valuable metal is continuously leached into the product stream (28). Consequendy, the soHd catalysts fail to eliminate the problems of corrosion and catalyst recovery and recycle that are characteristic of solution catalysis. [Pg.175]

Reactions of the Side Chain. Benzyl chloride is hydrolyzed slowly by boiling water and more rapidly at elevated temperature and pressure in the presence of alkaHes (11). Reaction with aqueous sodium cyanide, preferably in the presence of a quaternary ammonium chloride, produces phenylacetonitrile [140-29-4] in high yield (12). The presence of a lower molecular-weight alcohol gives faster rates and higher yields. In the presence of suitable catalysts benzyl chloride reacts with carbon monoxide to produce phenylacetic acid [103-82-2] (13—15). With different catalyst systems in the presence of calcium hydroxide, double carbonylation to phenylpymvic acid [156-06-9] occurs (16). Benzyl esters are formed by heating benzyl chloride with the sodium salts of acids benzyl ethers by reaction with sodium alkoxides. The ease of ether formation is improved by the use of phase-transfer catalysts (17) (see Catalysis, phase-thansfer). [Pg.59]


See other pages where Carbonylation catalysis is mentioned: [Pg.324]    [Pg.372]    [Pg.388]    [Pg.3377]    [Pg.3531]    [Pg.387]    [Pg.3376]    [Pg.3530]    [Pg.339]    [Pg.324]    [Pg.372]    [Pg.388]    [Pg.3377]    [Pg.3531]    [Pg.387]    [Pg.3376]    [Pg.3530]    [Pg.339]    [Pg.289]    [Pg.345]    [Pg.2783]    [Pg.47]    [Pg.98]    [Pg.529]    [Pg.265]    [Pg.458]    [Pg.488]    [Pg.14]    [Pg.465]    [Pg.41]    [Pg.62]    [Pg.70]    [Pg.183]   
See also in sourсe #XX -- [ Pg.12 , Pg.22 , Pg.180 ]

See also in sourсe #XX -- [ Pg.12 ]




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Acid catalysis carbonyl compounds

Acid catalysis carbonyl reactions

Amines catalysis of carbonyl condensation reactions

Asymmetric phase-transfer catalysis carbonyl compounds

Carbonyl compounds Brpnsted base catalysis

Carbonyl compounds catalysis

Carbonyl compounds enamine catalysis

Carbonyl compounds for metal catalysis

Carbonyl compounds hydrogenation, homogeneous catalysis

Carbonyl compounds intramolecular catalysis

Carbonyl compounds metal catalysis

Carbonyl compounds oxidation, palladium catalysis

Carbonyl compounds phase-transfer catalysis

Carbonyl compounds reactions under acid catalysis

Carbonyl compounds reactions under base catalysis

Carbonyl compounds synthesis, palladium catalysis

Carbonyl copper catalysis

Carbonyl enantioselective catalysis

Carbonyl groups metal catalysis

Carbonyl iron catalysis

Carbonyl nickel catalysis

Carbonyl platinum catalysis

Carbonyl ruthenium catalysis

Carbonyl titanium catalysis

Carbonyl zinc catalysis

Carbonylation industrial fine chemicals catalysis

Carbonylation reactions, catalysis

Carbonylation transition metal catalysis

Carbonylative catalysis

Carbonyls Important in Catalysis

Catalysis (cont molybdenum carbonyl

Catalysis by Cobalt Carbonyls

Catalysis carbonyl hydration

Catalysis carbonyl reactions

Catalysis in carbonyl substitution reactions

Catalysis methanol carbonylation

Cyclization-carbonylation palladium catalysis

Heterogeneous catalysis carbonylation with carbon

Heterogeneous catalysis with homogeneous carbonylation reaction

Intramolecular Catalysis of Carbonyl Substitution Reactions

Metal carbonyls chloride catalysis

Metal carbonyls, catalysis with

Nucleophilic carbonyl addition acid catalysis

Nucleophilic carbonyl addition base catalysis

Nucleophilic carbonyl addition reaction acid catalysis

Nucleophilic carbonyl addition reaction base catalysis

Palladium catalysis Alkene carbonylation

Palladium catalysis carbonylation

Palladium, dichlorobis catalysis halide carbonylation

Phase transfer catalysis synthesis of carbonyl compounds

Rhodium catalysis carbonylative coupling

Rhodium complexes methanol carbonylation catalysis

Styrene, a-methylasymmetric carbonylation catalysis by palladium complexes

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