Aryl bromides Suzuki reaction

Beller et al. have shown for the first time that palladium colloids are effective catalysts for the olefination of aryl bromides (Heck reaction). Reetz et al. have studied Suzuki and Heck reactions catalyzed by preformed palladium clusters and palladium/nickel bimetallic clusters and further progress was achieved by Reetz and Lohmert using propylene carbonate stabilized nanostructured palladium clusters as catalysts in Heck reactions. In addition, the use of nanostructured titanium clusters in McMurry-type coupling reactions has been demonstrated by Reetz et... 

Bromoquinolines behave in the Suzuki reaction similarly to simple carbocyclic aryl bromides and the reaction is straightforward. Examples include 3-(3-pyridyl)quinoline (72) from 3-bromoquinoline (70) and 3-pyridylboronic acid (71) (91JOC6787) and 3-phenyl-quinoline 75 from substituted 3,7-dibromoquinoline 73 and (2-pivaloylaminophenyl)boronic acid 74 (95SC4011). Notice that the combination of potassium carbonate and ethanol resulted in debromination at the C(7) position (but the... 

Suzuki coupling reactions with aryl halides. Two as-prepared BaCei cPd c03. ( materials (x = 0.05 and 0.10) were successfully utihzed in several Suzuki coupling reactions. Both aryl iodides and aryl bromides react smoothly with 4-phenylboronic acid, eq 1, to yield the corresponding biatyls in high yields (> 95%). For both 4-bromoanisole and 4-iodoanisole, the biatyl yields reached nearly 100% in 3 min with BaCeo 95Pdoo503 5 as the catalyst, corresponding to an effective TON of ca. 2,000 and an effective TOF of nearly 50,000 h. Resnlts are smmnarized in Table 27.1. 

Sterically demanding, water-soluble alkylphosphines 6.10 and 6.11 as ligands have been found to have a high activity for the Suzuki coupling of aryl bromides in aqueous solvents (Eq. 6.35).115 Turnover numbers up to 734,000 mmol/mmol Pd have been achieved under such conditions. Glucosamine-based phosphines were found to be efficient ligands for Suzuki cross-coupling reactions in water.116... 

Using a conventional dorm-room quality microwave oven, we have successfully performed Suzuki-Miyaura cross-coupling reactions catalyzed by Pd/C. Shorter reaction times are obtained (13 min of irradiation) using microwave irradiation compared to conventional methods of heating (> 1 h). Yields with relatively non-volatile aryl bromides range from 65 to 83%. Lower yields (15 - 27%) are obtained with relatively volatile aryl bromides substrates which may be evaporating during the course of the reaction. Ease of reaction set-up, rate enhancement from the microwave irradiation and facile work-up provided by the use of Pd/C makes this a very efficient procedure to mn. 

The pincer-type palladacycle (120) (R = 1Pr), which is actually a derivative of a dialkylphos-phinous acid (themselves excellent ligands see Section 9.6.3.4.6) was shown to allow the crosscoupling of aryl chlorides with terminal acetylenes ((120), ZnCl2, Cs2C03, dioxane, 160 °C). However the high reaction temperature may be prohibitive for the actual application of this catalytic system, as acetylenes are known to be thermally sensitive.433 The same palladacycle (R = Ph) is effective in the Suzuki-Miyaura reaction with aryl bromides and activated aryl chlorides (K2C03, toluene, 130 °C). 

Several microwave-assisted procedures have been described for soluble polymer-supported syntheses. Polyethylene glycol) (PEG)-supported aryl bromides have been shown to undergo rapid palladium(0)-catalyzed Suzuki couplings with aryl boronic acids in water (Scheme 12.16) [63], The reaction proceeded without organic cosolvent... 

A divergent protocol for a solid-phase synthesis of 3-substituted 2,5-biarylfurans was reported. Thus, reaction of furan zincate A with polymer bound aryl bromide or iodide provides resin intermediates 61. Subsequent bromination-Suzuki coupling reaction followed by further transformations gives rise to structurally diverse 2,3,5-trisubstituted furans 68 in good overall yields and chemical purities <00TL5447>. 

Buchwald has shown that, in combination with palladium(II) acetate or Pd2(dba)3 [tris(dibenzylideneacetone)dipalladium], the Merrifield resin-bound electron-rich dialkylphosphinobiphenyl ligand (45) (Scheme 4.29) forms the active polymer-supported catalysts for amination and Suzuki reactions [121]. Inactivated aryl iodides, bromides, or even chlorides can be employed as substrates in these reactions. The catalyst derived from ligand (45) and a palladium source can be recycled for both amination and Suzuki reactions without addition of palladium. 

In a simple strategy to biaryl formation, Han et al.89 showed that silicon-directed ipso-substitution and concomitant cleavage from supports could be used for formation of functionalized biphenyls. For this they used a tethered silyl aryl bromide in a Suzuki cross-coupling reaction, followed by the ipso-substitution/cleavage step (Scheme 39). A variety of boronic acids were coupled in this manner. The only difficulty occurred with electron-deficient nitrophenylboronic acid where the desired product was formed under anhydrous conditions in only 33% yield (the remainder being starting material). Reversion to the more usual conditions of aqueous base-DME (i.e., those used by Frenette and Friesen)70 improved the yield to 82%. 

Fluorous phase modifications of the Stille reaction were shown by Curran et al. to be accelerated by microwave irradiation.10 Similarly, Hallberg et al. demonstrated that such irradiation gives remarkably fast solid-phase Suzuki reactions, in the generation of biaryl units.9 Their reaction involved the coupling of a tethered (Rink amide TentaGel) aryl iodide or bromide with several boronic acids under 45 W of irradiation at 2450 MHz in sealed... 

Leadbeater and Marco also undertook to optimise the reaction conditions for ligand-free Suzuki reactions in water using both aryl bromides and chlorides. Comparisons between reactions performed under microwave irradiation and oil-bath heating led to the conclusion that the yields were identical or better with oil baths when aryl bromides were used as aryl precursors. However, comparisons between microwave and oil-bath heating with aryl chlorides as starting material clearly favoured the microwave technique38. 

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