Substrate oxidation reactions, trends

While such transition-state models have helped us to rationalize the patterns of selectivity observed in other reactions of 2-acyl- 1,3-dithiane 1-oxide substrates, such clear trends are not found in conjugate addition reactions (Table 3). One simple explanation for the poorer levels of stereoselectivity may be bond rotation within the acyl substituent, allowing the enone moiety to attain conformations other than those shown in 17 and 18. 

Studies of oxidation reactions of differing substrate types have been described. The nature of oxidant species in HCIO4 and H2SO4 media has been examined by investigation of catalysis of the Ce -Hg reaction. It is suggested that at 2.OM-HCIO4 the iridium(iv) is hydrolysed with protonation constant of 0.4 for [Ir(H20)s0H] +. Most kinetic studies, however, refer to reaction of the hexachloro and hexabromo ions. The oxidation of thiourea (tu), iV,iV -dimethyl-thiourea (dmtu), and 2-imidazolidinethione (it) follows a rate law second order in [substrate] and first in [Ir "]. The rate of oxidation follows the reactivity trend established previously for aquo-metal ions. The mechanism proposed involves rapid pre-equilibria followed by disulphide radical formation,... 

Mukaiyama s conditions have also been used in other aerobic oxidation reactions of substrates including thiols (Table 5.2, entries 1—4, 10 and 11), alkanes (entries 8, 12 and 14) and alcohols (entries 9 and 13), as well as reactions involving lactone formation via a Baeyer-ViUiger oxidation (entries 5-7) and oxidative decarboxylation (entry 16) [15-17]. While nickel, iron and cobalt aU selectively oxidize thiols to sulfoxides, Co(II) is the most active (entries 1—4) [15 b]. Of particular synthetic interest, the chemoselective and diastereoselective aerobic oxidation of the complex sulfide, exomethylenecepham (entries 10 and 11), was observed with no overoxidation to the suUbne or oxidation of the olefin [16 a]. The diverse substrate scope in entries 1-9 suggest iron and nickel species tend to have similar reactivity with substrates, but cobalt behaves differently. For example, both iron and nickel displayed similar reactivity in Baeyer-Villiger oxidations, with cobalt being much less active (entries 5-7), yet the opposite trend was observed for sulfide oxidation (entries 1—4) [15]. Lastly, illustrating the broad potential scope of Mukaiyama-type oxidations, alcohol oxidation (entries 9 and 13) and oxidative decarbonylation (entry 15) reactions, which are oxidase systems, have also been reported [16b, 17b]. 

Pyridine is a jt-electron-deficient heterocycle. Due to the electronegativity of the nitrogen atom, the a and y positions bear a partial positive charge, making the C(2), C(4), and C(6) positions prone to nucleophilic attacks. A similar trend occurs in the context of palladium chemistry. The a and y positions of halopyridines are more susceptible to the oxidative addition to Pd(0) relative to simple carbocyclic aryl halides. Even a- and y-chloropyridines are viable electrophilic substrates for Pd-catalyzed reactions under standard conditions. 

This trend is also observed in palladium chemistry where the general order for oxidative addition often correlates with that of nucleophilic substitution. Not only are 2-, 4- and 6-chloropyrimidines viable substrates for Pd-catalyzed reactions, but 4- and 6-chloropyrimidines react more readily than 2-chloropyrimidines. 

A comparison of the suitability of solvents for use in Srn 1 reactions was made in benzenoid systems46 and in heteroaromatic systems.47 The marked dependence of solvent effect on the nature of the aromatic substrate, the nucleophile, its counterion and the temperature at which the reaction is carried out, however, often make comparisons difficult. Bunnett and coworkers46 chose to study the reaction of iodoben-zene with potassium diethyl phosphite, sodium benzenethiolate, the potassium enolate of acetone, and lithium r-butylamide. From extensive data based on the reactions with K+ (EtO)2PO (an extremely reactive nucleophile in Srn 1 reactions and a relatively weak base) the solvents of choice (based on yields of diethyl phenylphosphonate, given in parentheses) were found to be liquid ammonia (96%), acetonitrile (94%), r-butyl alcohol (74%), DMSO (68%), DMF (63%), DME (56%) and DMA (53%). The powerful dipolar aprotic solvents HMPA (4%), sulfolane (20%) and NMP (10%) were found not to be suitable. A similar but more discriminating trend was found in reactions of iodobenzene with the other nucleophilic salts listed above.46 Nearly comparable suitability of liquid ammonia and DMSO have been found with other substrate/nucleophile combinations. For example, the reaction of p-iodotoluene with Ph2P (equation (14) gives 89% and 78% isolated yields (of the corresponding phosphine oxide) in liquid ammonia and DMSO respectively.4 ... 

These reactions provide yet another example of the generally observed trend (see Section II.B.3.c) that oxidations in the presence of high concentrations of metal catalysts proceed by different pathways than those in the presence of catalytic amounts. In the former case, direct reaction of the metal oxidant with the substrate is often implicated. At lower concentrations, the metal species produce chain-initiating radicals by reaction with peroxides. 

The indole oxidation has been shown to proceed via the hydroperoxide intermediate 9 (126), but whether this is formed via coordination catalysis, for example, as suggested in Reaction 41 for a phenol substrate (10— 12,13,14) (124), or via Haber-Weiss initiation, poses the same problem encountered in the organometallic type systems. A reactivity trend observed for Reaction 40 using tetraphenyl-porphyrin complexes (Co(II) Cu(II) Ni(II)) is reasonable in that the Co(II) system is known to give 1 1 02-adducts (at least, at low temperatures) but the reactivity trend also was observed for the catalyzed decomposition rate of 9. It is interesting to note that in Reac-... 

Even poor nucleophiles such as the amides 46 can react with azines in the presence of alkynes as activating agents [59, 60]. Various nucleophiles (including alkoxides, thiols, amines and nitrogen heterocycles) were recently employed in a related process with Ai-oxide azaindoles (Reissert-Henze reaction. Scheme 10). In the process, the oxygen is alkylated with dimethyl sulfate and, after the nucleophilic attack, methanol is released to aromatize the initial adduct [61,62]. Following similar mechanistic trends, V-heteroatom-activated azines afford the corresponding substituted adducts. Likewise, W-tosylated isoquinoline [63, 64] and W-fluoropyridinium salts [65] are also reactive substrates in Reissert-Henze type processes. 

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