Alkoxy intermediate reaction

Figure 9-16. An alternative route for the formation of the alkoxy intermediate by the reaction of alcohol with a high oxidation state metal oxo complex.

Review. New synthetic reactions based on the onium salts of aza-arenes have been reviewed (75 references). The reactions discussed involve activation of carboxylic acids or alcohols with 2-haIopyridinium, benzoxazolium, benzothiazolium, and pyridinium salts to afford 2-acyloxy or 2-alkoxy intermediates, which can be transformed into esters, amides, thiol esters, (macrocyclic) lactones, acid fluorides, olefins, allenes, carbodiimides, isocyanates, isothiocyanates, and nitriles under appropriate conditions. 

However, with the former catalyst the mechanism is essentially an ionic one, with evolution to a dioxyalkylidene species which can yield either methacrolein, or a carboxylate species, precursor of methacrylic acid. No isobutene is detected among the reaction products since the dioxyalkylidene species is strongly bound to the surface. The overall process involves the transfer of 8 electrons from the organic substrate to the catalyst per molecule of methacrylic acid produced. In the case of W-containing heteropolycompounds the mechanism is essentially a radical one (analogous to that proposed for the radical-like chemistry exhbited by W-containing heteropolycompounds in liquid phase oxidations (46)). In the absence of centres able to insert O species, the radical alkoxy intermediate converts to isobutene. The process only involves 2 electrons. 

The methoxy species formed by the dissociation of methanol can react with a second methanol molecule to give dimethyl ether and a proton. This is termed the alkoxy intermediate for the consecutive direct reaction mechanism. Alternative reaction paths exist which can be described as associative reaction mechanisms in which the product of an association reaction is formed without the formation of an alkoxy intermediate species . For two coadsorbed methanol molecules, the most stable adsorption mode does... 

Figure 4.31. Reaction energy diagram for the isomerization of hexene in mordenite. The 7r-complex denotes hydrogen-bonded alkene whereas the cr-complex denotes the corresponding alkoxy intermediate (schematic).

The oligomerization of propene on zeolite H-Y has been studied [33,37] by variable-temperature MAS NMR. Alkoxy species formed between protonated alkenes and oxygens of the zeolitic framework were found to be important long-lived intermediates in these reactions. Simple secondary or tertiary carbocations are either absent in the zeolite at low temperatures, or are so transient as to be undetectable by NMR even at temperatures as low as 163 K. There was, however, evidence for long-lived alkyl-substituted cyclopentenyl carbocations, which are formed as free ions in the zeolite at room temperature. At 503 K the oligomers crack to form branched butanes, pentanes and other alkanes. The final product was highly aromatic coke. The structure, dynamics and reactivity of an alkoxy intermediate formed from acetylene on zeolite catalysts have been investigated by Lazo et. al. [32]. 

With the use of these sensitivity-enhancement approaches the stable alkoxide intermediates were indeed detected by C CP/MAS NMR spectroscopy. Isopropoxide was the first alkoxy intermediate reliably identified in propylene labeled with C in the CH= group) conversion on zeolite HY [15]. Isopropoxide exhibits the signal at 87 ppm from the labeled C atom, which is characteristic of the (CH3)2CH fragment bonded to an oxygen atom of the zeolite framework (Fig. 20). Later, other alkoxide intermediates were detected and characterized. It was demonstrated that methoxides [121,122] and ethoxides [122,123] formed from methyl and ethyl iodides and also from methanol and ethanol on H-ZSM-5 and CsX zeolites. Isobutoxy [124] and tert-butoxy [90] intermediates resulted from the dehydration of isobutanol and tert-butanol on HZSM-5. Alkoxides are highly reactive species. For example, surface methoxides are effective methylating agents in their reactions with methanol, water, ammonia, alkyl halides, HCl, CO, acetonitrile, and aromatic compounds [125]. 

Dehydration of the intermediate p-alkoxy- or p-hydroxy ketone can also serve to drive the reaction to the right. 

As a unique reaction of Pd(II), the oxidative carbonylation of alkenes is possible with Pd(ll) salts. Oxidative carbonylation is mechanistically different from the hydrocarboxylation of alkenes catalyzed by Pd(0), which is treated in Chapter 4, Section 7.1. The oxidative carbonylation in alcohol can be understood in the following way. The reaction starts by the formation of the alkoxy-carbonylpalladium 218. Carbopalladation of alkene (alkene insertion) with 218 gives 219. Then elimination of /3-hydrogen of this intermediate 219 proceeds to... 

Anomalous Fischer cyclizations are observed with certain c-substituted aryl-hydrazones, especially 2-alkoxy derivatives[l]. The products which are formed can generally be accounted for by an intermediate which w ould be formed by (ip50-substitution during the sigmatropic rearrangement step. Nucleophiles from the reaction medium, e.g. Cl or the solvent, are introduced at the 5-and/or 6-position of the indole ring. Even carbon nucleophiles, e.g. ethyl acetoacelate, can be incorporated if added to the reaction solution[2]. The use of 2-tosyloxy or 2-trifluoromethanesulfonyloxy derivatives has been found to avoid this complication and has proved useful in the preparation of 7-oxygen-ated indoles[3]. 

The most suitable synthetic method for these products is the heterocyc-lization reaction of N-thioacyl derivatives of amino acids (202) with phosphorus tribromide (378, 442-450, 559, 560) or anhydrous trifluoroacetic acid (448, 449, 451, 452) (Scheme 103). Treatment of N-thioacyl amino acids with acetic anhydride leads directly to the thiazolylacetate without isolation of an intermediate thiazolinone (365. 452). 2-Alkoxy-derivatives of A-2-thiazoline-5-one, however, can be obtained without acetylation by this method (453, 454). 

Once formed the tetrahedral intermediate can revert to starting materials by merely reversing the reactions that formed it or it can continue onward to products In the sec ond stage of ester hydrolysis the tetrahedral intermediate dissociates to an alcohol and a carboxylic acid In step 4 of Figure 20 4 protonation of the tetrahedral intermediate at Its alkoxy oxygen gives a new oxonium ion which loses a molecule of alcohol m step 5 Along with the alcohol the protonated form of the carboxylic acid arises by dissocia tion of the tetrahedral intermediate Its deprotonation m step 6 completes the process... 

Where direct amination of chloro compounds has proved unsatisfactory, 4-alkoxy or 4-phenoxy intermediates have sometimes been used for reactions with amines or hydrazine. 

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