C-type tautomerism

Only for Z = O do the two columns produce similar K values. Af-type tautomerism gives similar values for Z = O and Z = S and C-type tautomerism for Z = S and Z = NR, but otherwise there is little point of contact. Amidines ( Af-type , Z=NR) are unique in that, since the same element is involved on both sides of the equilibrium, if R = R then K =1 necessarily. The values given are roughly correct throughout for R = R = R = Me and in many cases will extend to any of these as a straight-chain alkyl group, but this is not always correct and cannot be guaranteed. 

Figure 5.1 The distinction between "N-type" and C-type" tautomerism [1].

The characteristic property of aliphatic nitrocompounds of the type RCHiKOj and RjCHNO, is that they are pseiido cids, I. e., whereas they are neutral in the normal form (A), they are able by tautomeric change under the influence of alkali to give the acidic hydroxy form (B) which thus in turn gives the sodium salt (C). When this sodium salt is treated with one equivalent of hydrochloric acid, the acid form (B) is at once regenerated, and then more slowly reverts to the more stable normal form (A). 

Xanthene dyes (qv) can be either acidic or basic. Acid xanthenes are known to exist in two tautomeric forms. The phenoHc type, or fluorans, are free-acid stmctures such as D C Orange No. 10 (17b) and D C Red No. 21 (17c). Most have poor water solubHity. In contrast to these, the quinoids or xanthenes are usuaHy the highly water-soluble sodium salt counterparts of the fluorans such as D C Orange No. 11 (18) and D C Red No. 22 (21a). Presendy, there are no certifiable basic xanthene colorants. 

Dihydropyrroles (2-pyrrolines 231) are in tautomeric equilibrium with the corresponding 1-pyrrolines (232) the latter readily form trimers of type (233). The trimer dissociates in boiling THF to 1-pyrroline (232) trimerization is relatively slow at -78 °C and the monomer can be trapped by reaction with acylating reagents to give (V-acyl-2-pyrrolines (81JOC4791). 

The 1-oxide 3-oxide tautomerism [Eq. (3), p. 4] has been discussed earlier (Sections II and III,C) in connection with the problem of the structure of benzofuroxan. A second type of rearrangement involves the furoxan ring and an adjacent substituent group, and arose out of a suggestion of Bailey and Case that 4-nitro-benzofuroxan might be a resonance hybrid of type (57)-(-> (58), rather than 57. NMR ruled out this possibility the three protons present in... 

The second aspect is more fundamental. It is related to the very nature of chemistry (quantum chemistry is physics). Chemistry deals with fuzzy objects, like solvent or substituent effects, that are of paramount importance in tautomerism. These effects can be modeled using LFER (Linear Free Energy Relationships), like the famous Hammett and Taft equations, with considerable success. Quantum calculations apply to individual molecules and perturbations remain relatively difficult to consider (an exception is general solvation using an Onsager-type approach). However, preliminary attempts have been made to treat families of compounds in a variational way [81AQ(C)105]. 

Armulated thiophenes of types 195 and 197 (A benzo, naphtho) were studied concerning keto-enol tautomerism. The ring fusion has a remarkable influence upon these equilibria. Whereas for the c-fused thiophenes 197 only keto tautomers were present, for h-fused derivatives 195 also the enol forms 196 were found (the equilibria are solvent dependent) (82JOC705). 

A tautomeric equilibrium of 4-hydroxy-benzo[c]furan-3(l//)-ones of type 199 has been reported [R, R = Me, (CH2)4, (CH2)5] (89KGS24). 

Azide-tetrazole isomerism, or valence tautomerism, was not discussed for [5.6]bicyclic systems in the previous survey (76AHCS1). During recent years, this type of ring-chain tautomerism has been extensively studied for both six- and hve-membered heterocyclic azides. Tire tautomerism of [5.5]bicyclic tetrazole systems is covered in Section II,C. We discuss the tautomerism of the six-membered heterocyclic azides in this section. 

Infrared and ultraviolet spectral data indicate that 1,5-diaryl-pyrrolidine-2,3-diones exist in the monooxo form 68. Chemical evidence was advanced for a tautomeric equilibrium between 69 and 70, and later spectroscopic work showed that 70 was the predominant form. " Compounds of type 71 were formulated, without experimental evidence, in the oxo-imino form, although the tendency for C=NR—>C—NHR is usually greater than that for C=0—>C—OH in analogous cases. 

A different set of tautomeric tetrahydropyridines was obtained on partial hydrogenation of 2-alkoxy-3-acylpyridines 25 on PtOa or Pd/C catalyst (Scheme 9) (79JHC939). The tetrahydropyridines 26 formed exist exclusively as single tautomers, the type of tautomer, however, being determined by the substitution in the pyridine ring. 

If the carbanion has even a short lifetime, 6 and 7 will assume the most favorable conformation before the attack of W. This is of course the same for both, and when W attacks, the same product will result from each. This will be one of two possible diastereomers, so the reaction will be stereoselective but since the cis and trans isomers do not give rise to different isomers, it will not be stereospecific. Unfortunately, this prediction has not been tested on open-chain alkenes. Except for Michael-type substrates, the stereochemistry of nucleophilic addition to double bonds has been studied only in cyclic systems, where only the cis isomer exists. In these cases, the reaction has been shown to be stereoselective with syn addition reported in some cases and anti addition in others." When the reaction is performed on a Michael-type substrate, C=C—Z, the hydrogen does not arrive at the carbon directly but only through a tautomeric equilibrium. The product naturally assumes the most thermodynamically stable configuration, without relation to the direction of original attack of Y. In one such case (the addition of EtOD and of Me3CSD to tra -MeCH=CHCOOEt) predominant anti addition was found there is evidence that the stereoselectivity here results from the final protonation of the enolate, and not from the initial attack. For obvious reasons, additions to triple bonds cannot be stereospecific. As with electrophilic additions, nucleophilic additions to triple bonds are usually stereoselective and anti, though syn addition and nonstereoselective addition have also been reported. 

The values of 3/(NH,H) coupling constant observed for imine proton can be helpful in detection of the proton transfer processes and determination of mole fractions of tautomers in equilibrium. For NH-form, this value is close to 13 Hz, lower values usually indicate the presence of tautomeric equilibrium. It should be mentioned that the values below 2.4 Hz have not been reported. The chemical shift of C—OH (C-2 for imines, derivatives of aromatic ortho-hydroxyaldehydes or C-7 for gossypol derivatives) carbon to some extent can be informative, however, this value depends on type of substituents and should be interpreted with caution. 

In the fourth and final step, the intermediate 2-(2,-hydroxyphenyl)ethen-l-sulfmate (HPESi ) is desulfinated to 2-(2 -hydroxyphenyl)ethan 1-al (HPEal). As seen from Fig. 4, this step cannot be catalyzed by the arylsulfinate desulfinase like DszB. Instead, the enzyme has to be an alkenylsulfmate desulfinase. The alkenyl C-S bond as present in the intermediate, can only be desulfurized by hydroxylase-type enzyme, giving an enol, which can then tautomerize to HPEal and sulfite. However, the identity of the sulfur-containing product has not been confirmed [34],... 

---