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Esters formation, mechanism

Under CO pressure in alcohol, the reaction of alkenes and CCI4 proceeds to give branched esters. No carbonylation of CCI4 itself to give triichloroacetate under similar conditions is observed. The ester formation is e.xplained by a free radical mechanism. The carbonylation of l-octene and CCI4 in ethanol affords ethyl 2-(2,2,2-trichloroethyl)decanoate (924) as a main product and the simple addition product 925(774]. ... [Pg.263]

The mechanism of acid catalyzed ester hydrolysis is presented m Figure 20 4 It IS precisely the reverse of the mechanism given for acid catalyzed ester formation m Section 19 14 Like other nucleophilic acyl substitutions it proceeds m two stages A... [Pg.849]

Earlier reports have indicated that esters can form before significant amounts of acids accumulate (16). The Bayer-ViUiger oxidations of ketones with intermediate hydroperoxides and/or peracids have been suggested as ester forming mechanisms (34,56). However, the reactions of simple aUphatic ketones with peracetic acid are probably too slow to support this mechanism (57,58). Very early proposals for ester formation, although imaginative, appear improbable (59). [Pg.337]

The mechanisms of oxidation using bismuthate, periodate or lead tetraacetate, while still not completely understood, are probably similar, involving some type of cyclic ester formation as the first step. ... [Pg.149]

Acid chloride—con l d esters from, 802-803 from carboxylic acids, 794-795 Grignard reaction of, 804-805 hydrolysis of, 802 IR spectroscopy of, 822-823 ketones from, 805 mechanism of formation from carboxylic acids, 795 naming, 786... [Pg.1282]

However, if we consider the alternative nucleophilic displacement, it is known that nucleophilic processes are accelerated by ionic liquids, but more pertinent is the fact that the Sn2 displacement of iodide from alkyl iodide (Mel) by Rh(CO)2l2 is slightly accelerated by ionic liquids (7). Unfortunately, ionic liquids would also be expected to accelerate the nucleophilic displacement of iodide from ethyl iodide by propionic acid to form ethyl propionate (Reaction 8). In fact, as an Sn2 Type II displacement (the interaction of two neutral species), the ester formation from propionic acid and ethyl iodide would be expected to be significantly increased compared to the reaction of Rh(CO)2l2 with EtI. Therefore, by operating in iodide containing ionic liquids, we had set up a situation in which we suppressed the normally predominant hydride mechanism, slightly accelerated the alternative nucleophilic mechanism, but dramatically increased the ethyl propionate by-product forming pathway. [Pg.333]

The carboxyl end is known to catalyse both the polymerisation and hydrolysis reactions. The level of each is process dependant, with the ester interchange process tending to give the lowest carboxyl level in the final product. Some of the possible end groups in PET, along with their mechanisms of formation, are shown below in Figure 11. [Pg.183]

The mechanism of the ester formation would seem to be either an S i decomposition of the peroxide to give the ester directly, or a front side reaction between two acyloxy radicals. [Pg.27]

Scheme 1. Postulated mechanism of methanol and ethylene glycol ester formation... Scheme 1. Postulated mechanism of methanol and ethylene glycol ester formation...
The mechanism of phosphate ester hydrolysis by hydroxide is shown in Figure 1 for a phosphodiester substrate. A SN2 mechanism with a trigonal-bipyramidal transition state is generally accepted for the uncatalyzed cleavage of phosphodiesters and phosphotriesters by nucleophilic attack at phosphorus. In uncatalyzed phosphate monoester hydrolysis, a SN1 mechanism with formation of a (POj) intermediate competes with the SN2 mechanism. For alkyl phosphates, nucleophilic attack at the carbon atom is also relevant. In contrast, all enzymatic cleavage reactions of mono-, di-, and triesters seem to follow an SN2... [Pg.210]

Scheme 8.40. Synthesis of ABO esters selected examples. Mechanism of formation of ABO esters and tetrahydrofurans. Scheme 8.40. Synthesis of ABO esters selected examples. Mechanism of formation of ABO esters and tetrahydrofurans.
The last possibility for ester formation (20, Figure 12.15) comprises the reductive elimination of esters from acyl-alkoxy-palladium complexes 17, formed by deprotonation of the alcohol adducts 16. Clearly, it requires cis coordination of the alkoxide and acyl fragment. Since monodentates have a preference for ester formation, it was thought that this mechanism was very unlikely. [Pg.253]

It is important to note that in methanol as the solvent the reaction is much slower and also the molecular weight is much lower. Apparently a major part of the palladium complex occurs in an inactive state and the termination reaction is relatively accelerated by methanol. This suggests that ester formation is the dominant chain transfer mechanism in methanol, although P-hydride elimination will still occur. [Pg.258]

After E2/ubiquitin thiol ester formation, the ubiquitin must be transferred to the substrate, which is sometimes another ubiquitin. An E3 is usually required for this reaction in vitro, and is always required in vivo. There are three known types of E3s the RING domain, HECT domain, and U-box (UED2 homology) families. RING and U-box E3s act as bridging factors for E2s and substrates, but HEGT E3s use a different mechanism, adding an extra step to the pathway (Section 5.6.3.3). [Pg.113]

The influence of temperature on the ortho effect has been evaluated in the alkaline hydrolysis in aqueous DMSO solutions of ortho-, meta- and para-substituted phenyl benzoates (26). The alcoholysis of phthalic anhydride (27) to monoalkyl phthalates (28) occurs through an A-2 mechanism via rate-determining attack of the alcohol on a carbonyl carbon of the anhydride (Scheme 4). Evidence adduced for this proposal included highly negative A 5 values and a p value of 4-2.1. In the same study, titanium tetra-n-butoxide and tri-n-butyltin ethanoxide were shown to act as effective catalysts of the half-ester formation from (27), the mechanism involving alkoxy ligand exchange at the metal as an initial step. ... [Pg.41]

The stereochemical characterization of the adduct 53 follows from its NMR spectrum and a comparison with that of the l-(2-thienyl) compound (54). The aSY-exo configuration for the adducts 51 and 52 is consistent with the NMR spectra (hydrogen atoms at C-2, C-3, C-5, and C-6 all equivalent), with the proposed mechanism of formation, and with the failure of the related tetramethyl ester to xmdergo N-acetylation even in very vigorous conditions. N-substituted derivatives of compounds such as 51-53 may be obtainable directly from similar dipolar cycloaddition reactions of mesoionic N-substituted oxazolium 5-oxides, although the formation of only the N-methyl derivative of (52) has so far been reported. ... [Pg.94]

Figure 2. Mechanism of dihydroxyacetone/arsenate reaction with FDP aldolase. Both dihydroxyacetone and inorganic arsenate are not the inhibitor of the aldolase reactions. The rate constant for the arsenate ester formation is determined enzymatically (a plot of 1/v vs 1/E gives a non-zero intercept which is attributed to the rate at infinite enzyme concentration and that rate corresponds to the rate of nonenzymatic formation of the arsenate ester). Figure 2. Mechanism of dihydroxyacetone/arsenate reaction with FDP aldolase. Both dihydroxyacetone and inorganic arsenate are not the inhibitor of the aldolase reactions. The rate constant for the arsenate ester formation is determined enzymatically (a plot of 1/v vs 1/E gives a non-zero intercept which is attributed to the rate at infinite enzyme concentration and that rate corresponds to the rate of nonenzymatic formation of the arsenate ester).
Although the mechanism of ester formation has been the subject of some controversy, this process is related to polyborate formation in that both cases likely involve nucleophilic attack of an HO oxygen on B(OH)3 followed by elimination of water from a tetrahedral intermediate, Eq. (4). [Pg.17]

It has long been recognized that boron is required by higher plants [61, 62], and recent research indicates the involvement of boron in three main aspects of plant physiology cell wall structure, membrane function, and reproduction. In vascular plants, boron in solution moves in the transpiration stream from the roots and accumulates in the stems and leaves. Once in the leaves, the translocation of boron is limited and requires a phloem transport mechanism. The nature of this mechanism was only recently elucidated with the isolation of a number of borate polyol compounds from various plants [63-65]. These include sorbitol-borate ester complexes isolated from the floral nectar of peaches and mannitol-borate ester complexes from the phloem sap of celery. The implication is that the movement of boron in plants depends on borate-polyol ester formation with the particular sugar polyol compounds used as transport molecules in specific plants. [Pg.21]

Killday etal. (1988) also provided evidence for internal autoreduction of ferric nitrosyl heme complexes, as previously proposed by Giddings (1977). Heating of chlorohemin( iron-III) dimethyl ester in dimethyl sulfoxide solution with imidazole and NO produced a product with an infrared spectra identical to that of nitrosyl iron(ll) protoporphyrin dimethyl ester prepared by dithionite reduction. Both spectra clearly showed the characteristic nitrosyl stretch at 1663 and 1665 cm. They thus proposed a mechanism for formation of cured meat pigment which includes internal autoreduction of NOMMb via globin imidazole residues. A second mole of nitrite is proposed to bind to the heat-denatured protein, possibly at a charged histidine residue generated in the previous autoreduction step. [Pg.266]

The metal hydride mechanism was first described for the cobalt-carbonyl-catalyzed ester formation by analogy with hydroformylation.152 It was later adapted to carboxylation processes catalyzed by palladium136 153 154 and platinum complexes.137 As in the hydroformylation mechanism, the olefin inserts itself into the... [Pg.382]


See other pages where Esters formation, mechanism is mentioned: [Pg.224]    [Pg.470]    [Pg.1416]    [Pg.339]    [Pg.377]    [Pg.308]    [Pg.197]    [Pg.77]    [Pg.168]    [Pg.255]    [Pg.293]    [Pg.665]    [Pg.238]    [Pg.270]    [Pg.50]    [Pg.60]    [Pg.456]    [Pg.167]    [Pg.7]    [Pg.530]    [Pg.185]    [Pg.328]    [Pg.379]    [Pg.1096]   
See also in sourсe #XX -- [ Pg.95 ]




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