Aryl chlorides unactivated

Unlike aryl chlorides, unactivated alkenyl chlorides react more smoothly. It is generally recognized that alkenyl chlorides are much more reactive than aryl chlorides. However, curiously somewhat higher reactivity of chlorobenzene than the alkenyl chloride 75 was observed by the use of this catalyst in the following competitive reaction. The yield of 76 was higher than that of 77. 

Very recently Chen and co-workers have applied the previously mentioned Ni-based dimetallic pre-catalyst 14 in the Negishi reaction. Remarkable results were obtained even when unactivated aryl chlorides were chosen as reaction partners providing an alternative to the more expensive Pd-based catalysts. The fact that dinuclear pre-catalyst 14 is more active than its mononuclear analogue 13 indicates a possible cooperative effect between the two metal centres [86] (Scheme 6.23). 

Scheme 6.23 Nickel-catalysed Negishi coupling between unactivated aryl chlorides and oiganozinc reagents...

More recently Nolan has also reported a series of well-defined [Pd(Ti -allyl) Cl(NHC)] complexes (NHC = IPr, SIPr) with very high catalytic activity for this reaction, allowing the coupling of unactivated aryl chlorides in minutes. The presence of substituents in the terminal position of the allyl scaffold is necessary as they are proposed to favour catalyst activation. 

In summary, these results demonstrate that air-stable POPd, POPdl and POPd2 complexes can be directly employed to mediate the rate-limiting oxidative addition of unactivated aryl chlorides in the presence of bases, and that such processes can be incorporated into efficient catalytic cycles for a variety of cross-coupling reactions. Noteworthy are the efficiency for unactivated aryl chlorides simplicity of use, low cost, air- and moisture-stability, and ready accessibility of these complexes. Additional applications of these air-stable palladium complexes for catalysis are currently under investigation. 

Simple Pd salts and complexes which contain neither phosphines nor any other deliberately added ligands are well known to provide catalytic activity in cross-coupling reactions. Such catalytic systems (often referred to as ligand-free catalysts ) often require the use of water as a component of the reaction medium.17 In the majority of cases such systems are applicable to electrophiles easily undergoing the oxidative addition (aryl iodides and activated bromides), although there are examples of effective reactions with unactivated substrates (electron-rich aiyl bromides, and some aryl chlorides).18,470... 

Activated aryl chlorides, which are close in reactivity to unactivated aryl bromides, underwent reaction with the original P(o-tol)3-ligated catalyst.58 Nickel complexes, which catalyze classic C—C bond-forming cross-couplings of aryl chlorides, 9-64 also catalyzed aminations of aryl chlorides under mild conditions.65,66 However, the nickel-catalyzed chemistry generally occurred with lower turnover numbers and with a narrower substrate scope than the most efficient palladium-catalyzed reactions. 

Indoles, pyrroles, and carbazoles themselves are suitable substrates for palladium-catalyzed coupling with aryl halides. Initially, these reactions occurred readily with electron-poor aryl halides in the presence of palladium and DPPF, but reactions of unactivated aryl bromides were long, even at 120 °C. Complexes of sterically hindered alkylmonophosphines have been shown to be more active catalysts (Equation (25)). 8 102 103 In the presence of these more active catalysts, reactions of electron-poor or electron-rich aryl bromides and electron-poor or electron-neutral aryl chlorides occurred at 60-120 °C. Reactions catalyzed by complexes of most of the /-butylphosphines generated a mixture of 1- and 3-substituted indoles. In addition, 2- and 7-substituted indoles reacted with unhindered aryl halides at both the N1 and C3 positions. The 2-naphthyl di-t-butylphosphinobenzene ligand in Equation (25), however, generated a catalyst that formed predominantly the product from A-arylation in these cases. 

A variety of triazole-based monophosphines (ClickPhos) 141 have been prepared via efficient 1,3-dipolar cycloaddition of readily available azides and acetylenes and their palladium complexes provided excellent yields in the amination reactions and Suzuki-Miyaura coupling reactions of unactivated aryl chlorides <06JOC3928>. A novel P,N-type ligand family (ClickPhine) is easily accessible using the Cu(I)-catalyzed azide-alkyne cycloaddition reaction and was tested in palladium-catalyzed allylic alkylation reactions <06OL3227>. Novel chiral ligands, (S)-(+)-l-substituted aryl-4-(l-phenyl) ethylformamido-5-amino-1,2,3-triazoles 142,... 

A more general procedure for high-speed microwave-assisted Negishi and Kumada couplings of unactivated aryl chlorides has recently been reported by Walla and Kappe (Scheme 6.40) [82]. This procedure uses 0.015-2.5 mol% oftris(dibenzyl-... 

In early studies, it was observed that when the NHG was already attached to the metal center, reaction times were shortened since the time for the deprotonation of the salt and coordination to the metal center was no longer required. The use of well-defined systems also allows for a better understanding of the actual amount of stabilized palladium available in the system. Herrmann reported on two similar Pd(0) complexes bearing two carbenes, 37 and 38. The latter was used in 2002 as the first example of coupling of aryl chlorides (activated and unactivated) with arylboronic acids at room temperature, in high yields, and reaction times between 2 and 24 h in the presence of GsF as base. 

Dialkylphosphine oxides are another class of highly efficient ligands for coupling reactions using Pd or Ni (equation 85). Electron-poor fluoroazines and -diazines react already in the presence of NiClafdppp) , while hindered and electron-rich P(Bu-t)3 and (t-Bu)2P(S)H can be used for the coupling of unactivated aryl chlorides in the presence of Ni. 

Another one-pot, large-scale procedure for the preparation of thiophenols from unactivated aryl chlorides is available [7]. The reaction of an aryl chloride with a sodium alkanethiolate in NMP as a solvent affords, after acidification, the thiol in a high yield. 

Parrish and Buchwald30 performed couplings with a polystyrene-supported biphenyl-phosphine palladium complex between aryl halides and either amines (entry 24) or boronic acids (entry 25). The resin-bound complex is analogous to the corresponding homogeneous compound and is effective for couplings to unactivated aryl halides, including aryl chlorides. The complex is air-stable and retains activity after recovery without apparent loss of palladium. 

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