Cyclization, radicals compounds cycloaddition

Similar oxidative cyclization reactions involving the direct oxidation of acyclic 1,3-dicarbonyl compounds have not been reported. However, the generation of radical intermediates by the direct oxidation of cyclic 1,3-dicarbonyl compounds at an anode surface has been reported. Yoshida and coworkers have shown that the anodic oxidation of cyclic 1,3-dicarbonyl compounds in the presence of olefin trapping groups gives rise to a net cycloaddition reaction (Scheme 10) [23]. These cycloaddition reactions proceeded by initial oxidation of the 1,3-dicarbonyl compound at the anode followed by a radical addition to the second olefin. Following a second oxidation reaction, the material then... 

Scheme 29 describes a plausible mechanism for the formation of the products which fit the observed coulometric (n 0.45 F/mol) and preparative results. The intramolecular cyclization process involves a dimerization between a radical cation 52a and the ketene imine 52 to form the intermediate radical cation 52b which then cyclizes to the radical 52c which can abstract a hydrogen atom leading to 54 or can be further oxidized and transformed through a cyclization and deprotonation reaction to 53 which involves 1 F/mol. However, it seems that the [2 -1- 3]-cycloaddition between the parent compound 52 and the cation 52d giving rise to 55 is the fastest reaction as compared with the intramolecular cyclization of 52d to 53. This can also explain the low consumption of electricity. 

Recently it has been shown that radical anionic cyclization of olefinic enones effectively compete with intramolecular [2 -I- 2]-cycloaddition to form spirocy-clic compounds [205, 206], 3-Alkenyloxy- and 3-alkenyl-2-cyclohexenones 235 are irradiated in the presence of triethylamine. As depicted in Scheme 46 two reaction pathways may operate. Both involve electron transfer steps, either to the starting material (resulting in a direct cyclization) or to the preformed cyclobutane derivative 239, which undergoes reductive cleavage. The second... 

In intermolecular PET processes, radical ions are formed either as close pairs or as free species from neutral molecules (Sch. 1) [2,6]. Most commonly, carbonyl compounds or related derivatives as for example enol ethers, cyclopropyl ketones, and siloxycyclopropanes are used for intramolecular cyclization reactions. With the exception of cycloadditions the ring-building key step is always an intramolecular bond formation. In PET... 

Bischof and Mattay have shown that radical anion cyclization leading to spirocyclic products compete effectively with intramolecular [2 -f 2]-cycloaddition on photoexcitation of olefinic enones in the presence of triethylamine [332, 333]. The [2 -f 2] cycloadducts could be converted to the corresponding spiro compounds under PET conditions (Scheme 75) [307]. 

The incorporation of nitrogen into the enone system does not radically affect the cycloaddition reactions as seen in the (2+2)-addition reactions encountered with the enamides (48). In this study the influence of chain length on the intramolecular cyclization of the enones (48) has been evaluated. Thus with a four atom chain (48a) the product is the crossed addition compound (49a). With a six atom side chain (48b) the head-to-head adduct (50a) is formed exclusively while with a five atom chain (48c) a mixture of (49b) and (50b) is produced.The (2-f 2)-cycloadducts (51) are obtained in good yield on irradiation of the enone (52). The reaction is dependent on the nature of the substituent on C-3 and when this is H or Cl no cycloaddition reaction takes place on irradiation... 

Hart and Ghosh [43] have explored the 7-exo aryl and vinyl radical cyclizations for the construction of polycyclic systems as part of their tandem cycloaddition-radical cyclization strategies for polycycles. Treatment of the bromides 177-179 with BujSnH and AIBN furnished the tetra- and pentacyclic compounds 180-182 via stereoselective 7-exo trig cyclizations. 

It is also worthwhile comparing the intramolecular photochemical cycloaddition reactions of ethylenic aldehydes and ketones with free radical intramolecular additions. For instance, irradiation of 5-hexen-2-one (470) (Scheme 161) in the gas phase gives the oxetane 471 as only cyclized product, as expected from the known photochemical intermolecular reaction between olefins and ketones. If the irradiation is conducted in solution 470 gives 471 (26%) and 472 (18%). With other y,< -unsaturated ketones, the bicyclic compound analogous to 472 may become the major product. With 2-allylcyclanones such as 473 (Scheme 161) bicyclic compounds are obtained (80% yield) as a mixture of 474 and 475, with 475 being the major product, but such compounds are difficult to isolate. " In the same manner, selective irradiation of the carbonyl group of 2-acyl-2,3-dihydro-4/f-pyrans (476) leads exclusively (23% yield) to exo-brevicomin (477) (a sex attractant), neither oxetane formation nor Norrish type II reaction being observed. The formation of the compounds 472, 475, and 477 which was considered as unexpected... 

Apart from the described radical reaction pathways, there are several important side and consecutive reactions that also proceed in the cracking furnace. The higher the product concentration in the stream (i.e., at high feedstock conversion), the higher is the probability of these side and consecutive reactions. Important side and consecutive reactions include isomerization, cyclization, aromatization, alkylation, and also condensation reactions. The aromatic compounds found in the steam cracker product stream are formed, for example, by cycloaddition reactions of alkenes and dienes followed by dehydrogenation reactions. Moreover, monoaromatic compounds transform into aromatic condensates and polyaromatics (see also Scheme 6.6.2) by the same reactions. Typically, more than 100 different products are found in the product mixture of a commercial steam cracker. 

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