Enolization equilibrium

Polar solvents shift the keto enol equilibrium toward the enol form (174b). Thus the NMR spectrum in DMSO of 2-phenyl-A-2-thiazoline-4-one is composed of three main signals +10.7 ppm (enolic proton). 7.7 ppm (aromatic protons), and 6.2 ppm (olefinic proton) associated with the enol form and a small signal associated with less than 10% of the keto form. In acetone, equal amounts of keto and enol forms were found (104). In general, a-methylene protons of keto forms appear at approximately 3.5 to 4.3 ppm as an AB spectra or a singlet (386, 419). A coupling constant, Jab - 15.5 Hz, has been reported for 2-[(S-carboxymethyl)thioimidyl]-A-2-thiazoline-4-one 175 (Scheme 92) (419). This high J b value could be of some help in the discussion on the structure of 178 (p. 423). 

Certain structural features can make the keto-enol equilibrium more favorable by stabi hzmg the enol form Enolization of 2 4 cyclohexadienone is one such example... 

Dialkyl-3-hydroxyselenophenes exist in a keto-enol equilibrium 82 83 (72CS9). Analysis of the ionization potentials showed that for these compounds both the keto and the enol form are important [75ACS(B)652]. 

The amino form is usually much more favored in the equilibrium between amino and imino forms than is the hydroxy form in the corresponding keto-enol equilibrium. Grab and XJtzinger suggest that in the case of a-amino- and a-hydroxy-pyrroles, structure 89 increases the mesomeric stabilization and thus offsets the loss of pyrrole resonance energy, but the increase due to structure 90 is not sufficient to offset this loss. Similar reasoning may apply to furans and... 

A two-step sequence of nitrile oxide-olehn cycloaddition and reduction of the resulting A -isoxazolines offers a unique and attractive alternative to the classical aldol reaction and its many variants (2J). The procedure bypasses traditional problems, including enolate equilibrium and cross condensation (20). 

Enolizable compounds can be used for Meerwein reactions provided that the keto-enol equilibrium is not too far on the side of the ketone for example, P-dicar-bonyl compounds such as acetylacetone are suitable (Citterio and Ferrario, 1983). The arylation of enol esters or ethers (10.12) affords a convenient route for arylating aldehydes and ketones at the a-carbon atom (Scheme 10-48). Silyl enol ethers [10.12, R = Si(CH3)3] can be used instead of enol ethers (Sakakura et al., 1985). The reaction is carried out in pyridine. 

Other compounds with reactive methylene and methyl groups are completely analogous to the nitroalkanes. Compounds with ketonic carbonyl groups are the most important. Their simplest representatives, formaldehyde and acetone, were considered for many decades to be unreactive with diazonium ions until Allan and Podstata (1960) demonstrated that acetone does react. Its reactivity is much lower, however, than that of 2-nitropropane, as seen from the extremely low enolization equilibrium constant of acetone ( E = 0.9 x 10-7, Guthrie and Cullimore, 1979 Guthrie, 1979) and its low CH acidity (pK = 19.1 0.5, Guthrie et al., 1982). ... 

For a review of keto-enol equilibrium constants, see Toullec, J. in Rappoport, Ref. 314, p. 

An additional example of cycloamylose-induced catalysis which can probably be attributed to a microsolvent effect is the oxidation of a-hy-droxyketones to a-diketones (Scheme VIII). The rate of this oxidation is accelerated by factors ranging from 2.1 to 8.3 as the structure of the substrate is varied. As noted by Cramer (1953), these accelerations may be attributed to a cycloamylose-induced shift of the keto-enol equilibrium to the more reactive enol form. 

Regarding the first problem, the most elemental treatment consists of focusing on a few points on the gas-phase potential energy hypersurface, namely, the reactants, transition state structures and products. As an example, we will mention the work [35,36] that was done on the Meyer-Schuster reaction, an acid catalyzed rearrangement of a-acetylenic secondary and tertiary alcohols to a.p-unsaturatcd carbonyl compounds, in which the solvent plays an active role. This reaction comprises four steps. In the first, a rapid protonation takes place at the hydroxyl group. The second, which is the rate limiting step, is an apparent 1, 3-shift of the protonated hydroxyl group from carbon Ci to carbon C3. The third step is presumably a rapid allenol deprotonation, followed by a keto-enol equilibrium that leads to the final product. 

Alternatively, the synthesis may begin by condensing aniline with the l-chloro-2-carboxy intermediate. Acridone vat dyes of this type have excellent light fastness but only moderate resistance to alkali due to the keto-enol equilibrium. It is interesting that this pentacyclic dye is approximately 30 nm more bathochromic than the closely related tetracyclic 1-amino-2-benzoylanthraquinone. 

Fig. 6 The 2-(2-hydroxyphenyl)benzothiazole (HBT) unit that represents the keto-enol equilibrium (tautomerism). Normally, the enol (keto) form is rather stable in the ground state (in the excited state), respectively...

The bifluoride ion, HFj 297 Strong hydrogen bonding in p-diketones 309 Keto/enol equilibrium 310 Structures 312 Hydrogen-bond energies 314 Vibrational modes 315 Nmr spectroscopy 317... 

The keto/enol equilibrium (15) has been a spur to much research. In the absence of catalysts the equilibrium is established slowly and is very sensitive to a variety of influences, both internal, such as the nature of a- and P-substituents, and external, such as temperature and solvent. The discovery that the equilibrium was established sufficiently slowly to permit both keto and enol tautomers to be observed by H-nmr spectroscopy allowed these several influences to be easily investigated (see Kol tsov and Kheifets, 1971, for a review of the early work, and Emsley, 1984, for later work). 

A comprehensive study of the keto/enol equilibrium for pentane-2,4-... 

The carbonyl stretching frequency of both the keto and enol tautomers can be recognized in the vibrational spectrum of pentane-2,4-dione. The enol has v(C=0) at 1618cm" , generally the dominant peak in the spectrum and more intense than the in- and out-of-phase v(C=0) stretching modes of the keto form, which are found at 1727 and 1707 cm" , respectively. These are identified by their Raman counterparts at 1719 cm" (polarized) and 1697 cm" (depolarized) (Ernstbrunner, 1970). The ratio of absorbances of the enol and the out-of-phase keto bands in the ir was used as an early method of analysis of the keto/enol equilibrium in different solvents (Le Fevre and Welsh, 1949). 

To indicate the importance of enolization, equilibrium constants for a number of substrates are shown in Table 10.1. These equilibrium constants are only approximate, and they do depend very much on the solvents employed. Nevertheless, we can see that the equilibrium constant K = [enol]/[keto] is very small for substrates like acetaldehyde, acetone, and cyclohexanone, with only a few molecules in every million existing in the enol form. However, in ethyl acetoac-etate, enol concentrations are measured in percentages, and in acetylacetone the equilibrium constant indicates the enol form can be distinctly favoured over the normal keto form. In hexane solution, only 8% of acetylacetone molecules remain in the keto form. 

Jnmps of a proton along the hydrogen bond represent another type of dynamics observed in hydrogen-bonded complexes. Mechanistically, this process is simplest for intramolecular hydrogen bonds. The fast enol-enolic equilibrium shown in Scheme 2.2 illustrates an intramolecular proton-jumping system [27]. Here, substituent X dictates the equilibrium constant as well as the rate of proton transfer. It should be noted that such proton jumps can be stopped on the H NMR time scale only at very low temperatures. 

Scheme 2.2 Schematic representation of a proton-jumping molecular system with fast enol-enolic equilibrium between structures la and lb.

Ethers, reactions of, 315, 671, 1067, 1068 see also under Aliphatic ethers and Aromatic ethers. p-Ethoxyphenylurea, 646 p-Ethoxyproptonitrile, 915,916 Ethyl acetate, 383 purificatioh of. 174 Ethyl acetoacetate, 475, 476, 477 keto-enol equilibrium of, 475, 1148 purification of, 478 reactions of, 478 ... 

Many simple organic compounds exist as mixtures of two or more rapidly interconvertible isomers or tautomeric forms. Tautomers can sometimes be separated one from the other at low temperatures where the rate of interconversion is low. The classic example is the oxo-enol (or keto-enol) equilibrium (Eq. 2-1). 

Which tautomer is more stable Would you expect to be able to observe both tautomers at room temperature Rationalize any differences between this keto-enol equilibrium and that above involving acetone and propen-2-d. 

NMR studies have been mainly applied to elucidating the structural features of Schilf bases in solution. These studies are mainly concerned with SchiiT bases derived from benzaldehyde and its substituents, / -diketones, o-hydroxyacetophenones and o-hydroxyacetonaphthones. They were devoted to obtaining an insight into the keto-enol equilibrium (Scheme 1), syn and anti isomerism and steric distortions in different kinds of solvents. Relevant data and results are described in the following sections. 

Free ligands have been studied in order to obtain an insight into their structure, both in solution and in the solid state, and for comparison with their metal complexes. H NMR spectroscopy has been used to investigate the keto-enol equilibrium and the nature of the hydrogen bonds. In the case of optically active Schiff bases UV and CD spectra provided information about structure in solution. The Schiff bases that have been most widely examined are derivatives of acetylacetone, salicyl-aldehyde and hydroxymethylenecamphor, whose prototypes with en are shown in Figure 13. 

Table 8.6 Approximate Values of Keto-Enol Equilibrium Constants...

Rates of acid-catalysed enolization of isobutyrophenone and its ot-d analogue have been measured in H2O and D2O, by bromine scavenging.1403 Results include a solvent isotope effect, ku /kDi, of 0.56, and a substrate isotope effect, h/ d, of 6.2 (both for the enolization reaction). Combination of the data with that for ketonization in D2O140b gives the first isotope effect for the keto-enol equilibrium of a simple ketone e(H20)/ e(D20) = 0.92. The results are discussed in terms of the isotopic fiuctionation factors and the medium effect. 

Keto-enol equilibrium constants for simple /i-dicarbonyl compounds, RCOCH2COX (R = X = Me R = Me, Ph for X = OEt) have been measured in water1423 by a micelle perturbation method previously reported for benzoylacetone142b (R = Ph, X = Me). The results have been combined with kinetic data for nitrosation by NO+, C1NO, BrNO, and SCNNO in all cases, reaction with the enol was found to be rate limiting. 

A study of acid-catalysed enolization and carbon-acid ionization of isobutyrophenone has combined the solvent isotope effect k /kv = 0.56 and substrate isotope effect kH/kD = 6.2 determined for the enolization in H2O and D2O with literature information in order to estimate the solvent isotope effect on the enolization equilibrium, A e(H20)/A e(D20) = 0.92, and on the CH ionization of butyrophenone, kf (R20)/kK(D20) = 5.4.130 This is the first report of an isotope effect on AY forketo-enol equilibrium of a simple aldehyde or ketone. 

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