Arylation palladium chloride - tertiary phosphine

The acylpalladium halide complex 84 is an intermediate of catalytic decarbony-lation of aroyl halides 83 [53]. The decarbonylation of 84 generates the aryl-palladium intermediate 85 at higher temperature which undergoes facile alkene insertion. Therefore, similar to aryl halides, acyl halides can be used for the alkene insertion. The reaction is carried out with a phosphine-free Pd catalyst in the presence of tertiary amines [54]. Higher yields were obtained by using a mixture of K2CO3 and benzyltrioctylammonium chloride [55]. 

The asymmetric arylation or alkylation of racemic secondary phosphines catalyzed by chiral Lewis acids in many cases led to the formation of enantiomerically enriched tertiary phosphines [120-129]. Chiral complexes of ruthenium, platinum, and palladium were used. For example, chiral complex Pt(Me-Duphos)(Ph)Br catalyzed asymmetric alkylation of secondary phosphines by various RCH2X (X=C1, Br, I) compounds with formation of tertiary phosphines (or their boranes) 200 in good yields and with 50-93% ee [121]. The enantioselective alkylation of secondary phosphines 201 with benzyl halogenides catalyzed by complexes [RuH (/-Pr-PHOX 203)2] led to the formation of tertiary phosphines 202 with 57-95% ee [123, 125]. Catalyst [(R)-Difluorophos 204)(dmpe]Ru(H)][BPh4] was effective at asymmetric alkylation of secmidaiy phosphines with benzyl bromides, whereas (R)-MeOBiPHEP 205/dmpe was more effective in the case of benzyl chlorides (Schemes 65, 66, and 67) [125—127]. 

The main driving forces behind the development of new tertiary phosphine palladium complexes for C(sp )—C(sp) couplings have been (i) a reduction or elimination of side reactions, such as Glaser-type homocouplings (ii) the development of environmentally friendly reaction protocols, such as copper-free reactions in benign solvents (iii) the improvement of catalyst stabihty and activity [higher turnover number (TON) and turnover frequency (TOP)] and (iv) a cost reduction by using less-expensive aryl bromides, or even aryl chlorides under mild reaction conditions, for example, at ambient temperature. 

To this end, monodentate phosphine or bidentate PX (X=P, N, O) ligands have usually been employed as ancillary ligands for transition-metal-catalyzed reactions, with bulky tertiary alkyl phosphines proving particularly effective. Significant advances have been achieved in the use of less active aryl chlorides (bond strength C-Cl>C-Br>C-I) as chemical feedstock [5], with a number of processes mediated by palladium-bulky phosphine systems. This success is often explained by the effect of bulk and electron richness at the metal center along the catalytic cycle depicted in Fig. 1 [6]. 

On the other hand, true ligand acceleration (type 3 processes) shows preference for solvents of low polarity and lower Lewis basicity (toluene, dioxane and THF) with soluble tertiary amines as bases. In this respect, these Mizoroki-Heck reactions resemble cross-coupling processes, which also display strong preference for these solvents. Reactions in nonpolar solvents (toluene or xylene) have been known since Heck s seminal articles [8]. The halide remains a crucial subject of concern in reactions catalysed by phosphine complexes of palladium, aryl iodides prefer triarylphosphines and polar solvents, whereas reactions of aryl bromides and chlorides indeed prefer electron-rich trialkylphosphines and nonpolar solvents [63-65]. 

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