Nazarov cyclization photochemical reaction

A third and critical advance in the development of the Nazarov cyclization was the demtmstration that it belongs to the general class of cationic electrocyclic reactions (Scheme 4). This broadened its definition to include reactions which involve pentadienylic cations or equivalents and thus expanded the range of precursors for cyclopentenones. Further, the stereochemical features of electrocyclization enhanced the utility of the reaction and, in addition, stimulated the development of a photochemical variant. 

It is the structural variety of the precursors which lends versatility to the Nazarov cyclization and which also serves as the organizational framework for this chapter. To facilitate presentation die reaction is divided into five categories (i) (Lewis) acid-promoted and photochemical cyclization of divinyl and allyl vinyl ketones (ii) silicon- and tin-directed Nazarov cyclizations of divinyl ketones (iii) in situ generation/cyclization of divinyl ketones (iv) solvolysis to produce divinyl ketone equivalents (v) coupling reactions to form and cyclize divinyl ketones. The logic of this sequence follows from the order of decreasing structural similarity of the precursors to divinyl ketones. The last three subgroups encompass considerable structural diversity which will be discussed in each section. 

The Nazarov cyclization is an example of a 47r-electrocyclic closure of a pentadienylic cation. The evidence in support of this idea is primarily stereochemical. The basic tenets of the theory of electrocyclic reactions make very clear predictions about the relative configuration of the substituents on the newly formed bond of the five-membered ring. Because the formation of a cyclopentenone often destroys one of the newly created centers, special substrates must be constructed to aUow this relationship to be preserved. Prior to the enunciation of the theory of conservation of orbital symmetry, Deno and Sorensen had observed the facile thermal cyclization of pentadienylic cations and subsequent rearrangements of the resulting cyclopentenyl cations. Unfortunately, these secondary rearrangements thwarted early attempts to verify the stereochemical predictions of orbital symmetry control. Subsequent studies with Ae pentamethyl derivative were successful. - The most convincing evidence for a pericyclic mechanism came from Woodward, Lehr and Kurland, who documented the complementary rotatory pathways for the thermal (conrotatory) and photochemical (disrotatoiy) cyclizations, precisely as predicted by the conservation of orbital symmetry (Scheme 5). 

It should be pointed out that this reaction has been carried out photochemically (i.e., the photo-Nazarov cyclization Fi2) or under near-critical water conditions. More importantly, it has been improved to occur in a controllable fashion, through a directed Nazarov cyclization or an interrupted Nazarov reaction. It is worth noting that two practically directed Nazarov cyclizations have been developed, one by Denmark by using the jS-cation stabilizing effect and electrofuge of silicon (Scheme 2),2 > 2tt,6,i3 and the other from Ichikawa by application of a /3-cation destabilizing effect and the... 

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