Acetals heterolysis

The kinetic effect of increased pressure is also in agreement with the proposed mechanism. A pressure of 2000 atm increased the first-order rates of nitration of toluene in acetic acid at 20 °C and in nitromethane at 0 °C by a factor of about 2, and increased the rates of the zeroth-order nitrations of p-dichlorobenzene in nitromethane at 0 °C and of chlorobenzene and benzene in acetic acid at 0 °C by a factor of about 559. The products of the equilibrium (21a) have a smaller volume than the reactants and hence an increase in pressure speeds up the rate by increasing the formation of H2NO. Likewise, the heterolysis of the nitric acidium ion in equilibrium (22) and the reaction of the nitronium ion with the aromatic are processes both of which have a volume decrease, consequently the first-order reactions are also speeded up and to a greater extent than the zeroth-order reactions. 

The reaction of crotonaldehyde and methyl vinyl ketone with thiophenol in the presence of anhydrous hydrogen chloride effects conjugate addition of thiophenol as well as acetal formation. The resulting j3-phenylthio thioacetals are converted to 1-phenylthio-and 2-phenylthio-1,3-butadiene, respectively, upon reaction with 2 equivalents of copper(I) trifluoromethanesulfonate (Table I). The copper(I)-induced heterolysis of carbon-sulfur bonds has also been used to effect pinacol-type rearrangements of bis(phenyl-thio)methyl carbinols. Thus the addition of bis(phenyl-thio)methyllithium to ketones and aldehydes followed by copper(I)-induced rearrangement results in a one-carbon ring expansion or chain-insertion transformation which gives a-phenylthio ketones. Monothioketals of 1,4-diketones are cyclized to 2,5-disubstituted furans by the action of copper(I) trifluoromethanesulfonate. ... 

Therefore any flexible acetal will undergo conformational changes to permit 2p(0) <-> 2p(C+) stabilizing interaction to intervene in the transition state of its heterolysis. This is also true for pyranosides for which the free energy difference between chair, boat and sofa conformers rarely surpasses 10 kcal/mol. 

Suitably protected glycosyl halides or acetates, upon Lewis-acid promoted SN1 heterolysis, generate glycosyl cation intermediates that can react with electron-rich arenes, heteroarenes, Me3SiCN, enoxysilanes, enamines, allyl silanes and stannanes, acetylenyl silanes and stannanes affording C-glycosyl compounds. 

The mechanism of the acid-catalyzed hydrolysis of cellulose is based on that normally expected for an acetal (see Scheme 11). This involves formation of a conjugate acid by protonation of either of the acetal oxygen atoms at C-1, and formation of a carbonium ion, followed by stabilization of the product by heterolysis of a participating water molecule. The car-... 

Our preliminary experiments have provided the first example of Lewis acid promoted C-C bond heterolysis of epoxides and productive cycloaddition (eq 7). Under the influence of TiCl4-(THF)2 (2 equiv), epoxide 26 reacts with methyl pyruvate to provide acetal 27 (52% isolated yield), along with C-O cleavage product 28 (23 °C, 3 h). The diaste-reoselectivity for formation of 27 is 2.3 1. We have performed the analogous reaction in the absence of a Lewis acid the thermal reaction requires several days at 110 °C and gives a diastereomer ratio (dr) of ca. 1.3 1... Although not optimized from the standpoint of chemoselectivity, these results are promising because of the relatively low reaction temperature and potential for enhanced diastereocontrol. 

Mechanistically, the authors favored a thiourea 9-assisted heterolysis of the orthoester through hydrogen bonding as the entry into the catalysis cycle of the organocatalytic acetalization. The orthoester was suggested to serve as the source of the alcoholate, which rapidly attacks the carbonyl compound to form a... 

Scheme 6.11 Proposal for the catalytic cycle of the acid-free, organocatalytic acetalization induced by 9-assisted orthoester heterolysis.

Other Reactions of Olefinic Steroids.—Reaction of cholest-5-en-3-one with air and acetic acid shows that isomerization to the A -3-oxo-compound is accompanied by autoxidation to the 6a- and 6/8-hydroxy-3-oxo-A -compounds and the 3,6-dioxo-A -compound. The oxidation appears to be controlled by heterolysis of the 4/3-proton and formation of the intermediate ion pair (73). Sitosterol was autoxi-dized at C-7 to give the 7-oxo- and the epimeric 7-hydroxy-derivatives. Oxidation of a 17-methylene steroid with Pb, Tl" , and Hg acetates in methanol gave a wide variety of products. The reaction with Pb(OAc)4 gave the rearranged products (74), (75), and (76) whereas the Tl and Hg products retained the... 

Furthermore, the heterolysis reaction is catalyzed by the addition of anions (organic and inorganic oxy anions, e.g., acetate) (44,107, 110,111). Comparing the acetate effect in the presence of different chelating ligands ([15]aneN4 and nta) to those of the aquated system led to the conclusion that the oxy anions have to occupy the trans position to the R group in order to labilize the M-R bond (trans labilization effect) and thus catalyze the heterolytic decomposition (44,107,110,111). 

Reactions of rhodium(III) porphyrins with olefins and acetylenes - Ogoshi et al. [326] have described the reactions of vinyl ether with rhodium (III) porphyrins which are depicted in reaction sequence (33). Step (a) appears to be an insertion of the olefin into the Rh-Cl bond followed by alcoholysis of a chlorosemiacetal to the acetal, step (b) is the hydrolysis of the acetal to the aldehyde. The insertion is thought to start by heterolysis of the Rh-Cl bond producing a cationic species which forms a 7i-complex with the electron-rich olefin. 

The second subset of acid labile protecting groups consists of 0,0-acetals. Like the protecting groups in the first subset, heterolysis of an OtO-aceta] is induced by protic acids and Lewis acids resulting in formation of a resonance stabilised intermediate — an oxonium ion 6 1 [Scheme 1.6]. In the presence of nucleophiles (e.g, water), the highly electrophilic oxonium ion reacts further to pro-... 

A further example for heterolysis of the acetate function are radicals from glycerol esters, see ref 75. 

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