Ketone-olefin coupling

In 1986, Belotti, Pete and Portella reported that intramolecular ketone/olefin coupling could be achieved via photoinduced electron transfer (irradiation of an aliphatic ketone in HMPA)78. Several examples of this chemistry are highlighted below (Scheme 26). Intramolecular additions to C=C and allenes were also reported with yields in the range 70-80% however, additions to C=N were unsuccessful. 

Analogous intramolecular chelation-controlled ketone/olefin couplings with Sml2, in which Sm+3 was complexed in a cyclic manner to the ketyl anion and a /1-carbonyl of an ester or amide functionalilty, were reported as early as 1987 (Scheme 31)86. The cyclized samarium intermediate 49 could be further reacted with added electrophiles such... 

For additional examples of ketone/olefin coupling reactions promoted by Sml2, see ... 

For further applications of samarium iodide promoted ketone-olefin couplings see M. Kawatsura, K. Hosaka, F. Matsuda and H. Shirahama, Synlett, 1995, 729. 

Matsuda et al. have studied the hydroxyl group directed intermolecular ketone-olefin coupling reactions, induced by Sml2, between a-hydroxy ketones and a,P-unsaturated esters or nitriles (Scheme 30). It was noted that reactions... 

The intramolecular reductive ketone-olefin coupling was realized by Molan-der et al. by the combination SmI2/THF-f-BuOH [126]. For example, the spiro-... 

Another class of chelation-controlled reactions involves Sml2, which has been used to mediate inter- and intramolecular ketone-olefin couplings [17], Matsuda and collaborators showed that coupling erpt/ira-) -hydroxyketone with acrylonitrile led exclusively to the anti diol under Sml2 reductive conditions [18]. Chelation control model J in Scheme 6 was proposed to account for the sense of diastereo-selectivity. In this model, chelation of the Smb to both the jff-hydroxy and the... 

This C-H/olefin coupling can be extended to coupling with acetylenes [6], The reaction of aromatic ketones with internal acetylenes gives the ortho alkenylated product in high yield (Scheme 2), but reaction with terminal acetylenes does not afford the coupling product. With terminal acetylenes, dimerization of acetylenes occurs as a predominant reaction. 

In (C5Me5)Rh(C2H3SiMe3)2-catalyzed C-H/olefin coupling the effect of the coordination of the ketone carbonyl is different from that in the ruthenium-catalyzed reaction [10], In the rhodium-catalyzed reaction all C-H bonds on the aromatic ring are cleaved by the rhodium complex without coordination of the ketone carbonyl. Thus, C-H bond cleavage and addition of Rh-H to olefins proceed without coordination of the ketone carbonyl. After addition of the Rh-H species to the olefin, a coordinatively unsaturated Rh(aryl) (alkyl) species should be formed. Coordination of the ketone carbonyl group to the vacant site on the rhodium atom leads... 

The ruthenium-catalyzed addition of C-H bonds in aromatic ketones to olefins can be applied to a variety of ketones, for example acetophenones, naphthyl ketones, and heteroaromatic ketones. Representative examples are shown in the Table 1. Terminal olefins such as vinylsilanes, allylsilanes, styrenes, tert-butylethy-lene, and 1-hexene are applicable to this C-H/olefin coupling reaction. Some internal olefins, for example cyclopentene and norbornene are effective in this alkylation. The reaction of 2-acetonaphthone 1 provides the 1-alkylation product 2 selectively. Alkylations of heteroaromatic ketones such as acyl thiophenes 3, acyl furans, and acyl pyrroles proceed with high yields. In the reaction of di- and tri-substitued aromatic ketones such as 4, which have two different ortho positions, C-C bond formation occurs at the less congested ortho position. Interestingly, in the reaction of m-methoxy- and m-fluoroacetophenones C-C bond formation occurs at the congested ortho position (2 -position). 

Several related examples of transition metal-catalyzed addition of C-H bonds in ketones to olefins have been reported (Table 2) [11-14]. The alkylation of diterpenoid 6 with olefins giving 7 proceeds with the aid of Ru(H)2(CO)(PPh3)3 (A) or Ru(CO)2(PPh3)3 (B) as catalyst [11], Ruthenium complex C, Ru(H)2(H2)(CO) (PCy3)2, has catalytic activity in the reaction of benzophenone with ethylene at room temperature [12]. The alkylation of phenyl 3-pyridyl ketone 8 proceeds with A as catalyst [13], Alkylation occurs selectively at the pyridine ring. Application of this C-H/olefin coupling to polymer chemistry using ce,co-dienes such as 1,1,3,3-tetramethyl-l,3-divinyldisiloxane 11 has been reported [14]. 

Intramolecular olefinic C-H/olefin coupling with the aid of Ru(CO)3(PPh3)2, which is also effective for the reaction of aromatic ketones with olefins, yields the carbocyclic compounds in excellent yield (Eq. 42) [67]. This type of cy-clization reaction can be extended to an asymmetric version when the [RhCl(coe)2]2/PPFOMe catalyst system is employed [68]. 

PET reaction of carbonyl compounds with olefins form either oxetanes (Paterno-Buchi reaction, Eq. 31) by direct coupling or a radical pair reaction leading to coupling product or reduction. The carbonyl-olefin radical pairs are formed by proton transfer within their radical ion pairs (Eq.32). Both these aspects of ketone-olefin photoreaction have been recently rationalized by Mattay et al. [167] from the photoreactions of 2,3-butanedione (208) with different olefins such as 209 and 210 as shown in Scheme 39. Photoprocesses of... 

The relationship between the structure and the reactivity of the ketones has been studied [4cj. When 3-acetylthiophene was used in the coupling reaction, the alkylation took place only at 2-position (Eq. 9.2). In the cases of reactions of the ketones, shown in Scheme 9.1, no coupling product was obtained. Based on these results, Murai proposed that the a,/3-conjugate enone framework is important in the C-H/ olefin coupling reaction. 

In 1996, the present authors extended their C-H/olefin coupling to the C-H/ CO/olefin coupling reaction [40]. Carbonylation of imidazole derivatives takes place in the presence of Ru3(CO)12 as the catalyst. The C-C bond formation occurs at the 4-position (Eq. 26). In these reactions, the linear ketones are the major products. Various functional groups, e.g., nitrile acetal, and ether, are tolerant. 

An analogous ruthenium dihydride complex. RuH2(CO)(PPh3)3, has recently attracted much attention because of its ability to catalyze olefin coupling reactions of aromatic ketones via C—H bond activation (eq (46)) [152]. 

Figure 10.4 A possible intermediate in the olefin coupling reaction of aromatic ketone catalyzed by RuH2(CO)(PPh3)3. Other ligands are omitted.

No unusual couplings nor coupling constants are observed in the NMR spectra of the Ketones. The aliphatic three bond vicinal coupling JHC-CH is 6-8 Hz, the aromatic ortho coupling constant varies from 8-9 Hz, and the olefinic coupling constants display the values listed. 

Ketyls generated by the reaction of SmE with aldehydes and ketones have been incorporated into numerous sequential processes in which a radical reaction is involved. Sequential radical processes, radical cyclization/carbonyl additions, radical cyclization/substitution reactions, nucleophilic acyl substitution/radical cyclizations, cyclization/elimination processes, and others have all been realized. Because these types of reactions have been extensively reviewed [2b, 25], further details will not be given here. Needless to say, new sequential processes based on SmE-promoted ketyl/olefin coupling reactions are still being developed (Eq. 75) [88]. 

---