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Mizoroki-Heck reaction carbopalladation

While the PNP dimer was an efficient catalyst for the ort/toalkylation/ Mizoroki-Heck reaction, the practicality of the transformation is lessened by the fact that the PNP dimer is not commercially available, and can be quite difficult to prepare. Thus, Catellani adapted the reaction conditions to include commercially available and air-stable Pd(OAc)2 as the catalyst source [46], Under these conditions, the ortho-u kylation/Mizoroki-I Ieck coupling of aryl iodides containing a pre-existing ortho substituent could be carried out. The reaction required higher temperatures, and the addition of KOAc to promote the carbopalladation of norbomene [47] and encourage the o/t/zo-alkylation pathway vs a direct Mizoroki-Heck coupling. [Pg.15]

A mechanism is now proposed for Mizoroki-Heck reactions involving Pd(OAc)2 as precursor associated with PPh3 (Scheme 1.22). From the rate constants of the main steps given in Scheme 1.22, it appears that, for comparable iodobenzene and styrene concentrations, the overall carbopalladation (complexation/insertion of the alkene) from PhPd(OAc)(PPh3)2... [Pg.14]

This is illustrated in the mechanism of the Mizoroki-Heck reaction depicted in Scheme 1.22. Indeed, three main factors contribute to slow down the fast oxidative addition of Phi (i) the anion AcO delivered by the precursor Pd(OAc)2, which stabilizes Pd L2 as the less reactive Pd°L2(OAc) (ii) the base (NEts) which indirectly stabilizes Pd L2(OAc) by preventing its decomposition by protons to the more reactive bent Pd L2 (iii) the alhene by complexation of Pd°L2(OAc) to form the nonreactive ( -CH2=CHR)Pd°L2(OAc). On the other hand, the slow carbopalladation is accelerated by the base and by the acetate ions which generate ArPd(OAc)L2, which in turn is more reactive than the postulated ArPdIL2. The base, the alkene and the acetate ions play, then, the same dual role in Mizoroki-Heck reactions deceleration of the oxidative addition and acceleration of the slow carbopalladation step. Whenever the oxidative addition is fast (e.g. with aryl iodides or activated aryl bromides), this dual effect favours the efficiency of the catalytic reaction by bringing the rate of the oxidative addition closer to the rate of the carbopalladation [Im, 34]. [Pg.15]

Regioselectivity is one of the major problems of Mizoroki-Heck reactions. It is supposed to be affected by the type of mechanism ionic versus neutral, when the palladium is ligated by bidentate P P ligands. The ligand dppp has been taken as a model for the investigation of the regioselectivity. Cabri and Candiani [Ig] have reported that a mixture of branched and linear products is formed in Pd°(P P)-catalysed Mizoroki-Heck reactions performed from electron-rich alkenes and aryl halides (Scheme 1.26a) or aryl ttiflates in the presence of halide ions (Scheme 1.26b). This was rationalized by the so-called neutral mechanism (Scheme 1.27). The neutral complex ArPdX(P P) is formed in the oxidative addition of Pd°(pAp) yj Qj. Q aj.yj triflates in the presence of halides. The carbopalladation... [Pg.18]

As established above, the regioselectivity of Mizoroki-Heck reactions performed in DMF is sensitive to the presence of coordinating anions such as hahde or acetate (Scheme 1.35). The carbopalladation step always proceeds from the more reactive cationic complex ArPd5"(dppp)+ (Schemes 1.35 and 1.36), not from neutral ArPdX(dppp), except for the reaction of ArPdl(dppp) with the most reactive methyl acrylate, performed in the absence of acetate ions (Schemes 1.34 and 1.37). [Pg.25]

Very recently, the same group [22] performed the synthesis of acenaphthylenes 20 by a combination of a Mizoroki-Heck reaction and an unexpected C—H activation by treatment of a series of alkynes 19 with palladium(O). Acenaphthylenes 20 were obtained as single products in high yields in those cases where R is an aryl moiety. When aliphatic alkynes are used, the yield drops considerably. It can be assumed that, after oxidative addition, a ciT-carbopalladation of the triple bond takes place to give a vinyl-palladium intermediate which undergoes the C—H insertion into the adjacent naphthalene and not into the aryl ether moiety in 19a-e (Scheme 8.4). [Pg.285]

All reactions described in this section are explained by (i) the oxidative addition of a halide to generate the arylpalladium halide 14 (ii) insertion of an alkene to form 15, which is regarded as carbopalladation of alkenes and (iii) formation of the new alkene 16 by elimination of /I-hydrogen (dehydropalladation). The reaction was reported independently by Mizoroki [3] and by Heck [4], and is called the Mizoroki Heck or Heck reaction [5]. [Pg.33]

Over 35 years ago, Richard F. Heck found that olefins can insert into the metal-carbon bond of arylpalladium species generated from organomercury compounds [1], The carbopalladation of olefins, stoichiometric at first, was made catalytic by Tsutomu Mizoroki, who coupled aryl iodides with ethylene under high pressure, in the presence of palladium chloride and sodium carbonate to neutralize the hydroiodic acid formed (Scheme 1) [2], Shortly thereafter, Heck disclosed a more general and practical procedure for this transformation, using palladium acetate as the catalyst and tri-w-butyl amine as the base [3], After investigations on stoichiometric reactions by Fitton et al. [4], it was also Heck who introduced palladium phosphine complexes as catalysts, enabling the decisive extension of the ole-fination reaction to inexpensive aryl bromides [5],... [Pg.277]


See other pages where Mizoroki-Heck reaction carbopalladation is mentioned: [Pg.14]    [Pg.12]    [Pg.4]    [Pg.12]    [Pg.42]    [Pg.268]    [Pg.268]    [Pg.276]    [Pg.309]    [Pg.542]    [Pg.311]    [Pg.21]    [Pg.6]   
See also in sourсe #XX -- [ Pg.516 ]




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