Cross-coupling catalysis

Keywords Allylic substitution Catalysis Cross-coupling Cycloaddition Cycloisomerisation DNIC Ferrate Hydrogenase Iron... 

Keywords Homogeneous catalysis Cross-coupling Microwave Heck Sonogashira Buchwald-Hartwig... 

Keywords Addition Catalysis Cross-coupling Cyclization Electron transfer Radicals Transition metals... 

Keywords Catalysis Cross-coupling reaction Electronic properties Metathesis N-heterocydic carbene Topology... 

Radicals and carbenes ch37 ch38 metal to carbon are key steps Carbon monoxide inserts into metal-carbon bonds Palladium is the most important metal C-C, C-0, and C—N bonds can be made with Pd catalysis Cross-coupling of two ligands is common Allyl cation complexes are useful electrophiles ... 

The thioboration of terminal alkynes with 9-(alkylthio)-9-borabicyclo[3.3.1]-nonanes (9-RS-9-BBN) proceeds regio- and stereoselectively by catalysis of Pd(Ph,P)4 to produce the 9-[(Z)-2-(alkylthio)-l-alkeny)]-9-BBN derivative 667 in high yields. The protonation of the product 667 with MeOH affords the Markownikov adduct 668 of thiol to 1-alkyne. One-pot synthesis of alkenyl sulfide derivatives 669 via the Pd-catalyzed thioboration-cross-coupling sequence is also possible. Another preparative method for alkenyl sulfides is the Pd-catalyzed cross-coupling of 9-alkyl-9-BBN with l-bromo-l-phe-nylthioethene or 2-bromo-l-phenylthio-l-alkene[534]. 

Tamao K, Miyaura N (2002) Introduction to Cross-Coupling Reactions. 219 1-9 Tanaka M (2003) Homogeneous Catalysis for H-P Bond Addition Reactions. 232 25-54 Tanner PA (2004) Spectra, Energy Levels and Energy Transfer in High Symmetry Lanthanide Compounds. 241 167-278 ten Cate MGJ, see Crego-Calama M (2005) 249 in press ten Holte P,see Zwanenburg B (2001) 216 93-124 Thiem J,see Werschkun B (2001) 215 293-325... 

Scheme 28 Domino iron catalysis for cross-coupling of alkyl and aryl halides [90]...

Transition metal-catalysed reactions have emerged as powerful tools for carbon-carbon (C-C) bond formation [1], Cross-coupling reactions (Suzuki-Miyaura, Mizoroki-Heck, Stille, etc.) are recognised to be extremely reliable, robust and versatile. However, some other catalysed arylation reactions have been studied and have been reported to be very efficient [2]. In recent years, A -heterocyclic carbenes (NHC) have been extensively studied and their use as ligands for transition-metal catalysis has allowed for the significant improvement of many reactions [3]. This chapter highlights the use of NHC-bearing complexes in those arylation reactions. 

During the past decade, NHCs have been coordinated to virtually all transition metals (TM) and studied in numerous catalytic transformations, pushing back the frontiers of catalysis. In this regard, the most salient examples are found in olefin metathesis and cross coupling reactions, and more recently in organocatalysis. 

Similarly, nickel catalysis permits the extension of cross coupling to vinyl phosphates, which are in some cases more readily obtained and handled than vinyl triflates.273... 

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. 

Supported ultra small palladium on magnetic nanopartides used as catalysts for Suzuki cross-coupling and Heck reactions. Advanced Synthesis and Catalysis, 349, 1917-1922. 

Aryl-aryl or Aryl-heteroaryl cross-coupling reactions can be performed with either Ni- or Pd-based catalysis. Due to the low reaction temperatures, substrates containing some additional functional groups are tolerated (26).138... 

Alternatively, the transmetalation can be facilitated by increasing the nucleophilicity of the carbon nucleophile participating in the cross-coupling, which is most often done by increasing the electron density on the metal by coordination of extra anionic ligands. Two distinct approaches to nucleophilic activation are (i) the addition of appropriate Lewis bases to the reaction mixture (nucleophilic catalysis) or (ii) the use of a preformed, electron-rich, organo-metallic reagent with enhanced nucleophilicity. 

The ideal ligand for the cross-coupling reactions should satisfy the requirements of all stages of the catalytic cycle. In practice this is unlikely, as these requirements are not parallel. A careful compromise between various factors is necessary for any particular realization of cross-coupling chemistry. The path of reasoning should be similar for both Pd- and Ni-catalyzed processes however, since very little information is available concerning Ni catalysis, only Pd catalysis will be discussed here. 

Commercially available Pd(PtBu3)2 is a unique, air-stable 14e Pd° complex, an excellent catalyst for cross-coupling reactions of aryl chlorides. The ability of P Bu3 to stabilize such a coordin-atively unsaturated, extremely reactive, and yet easily manageable form of Pd° is one of the most amazing and fruitful recent findings in Pd-based catalysis. The cross-coupling of arylzinc reagents with aryl or vinyl chlorides can be readily accomplished with as little as 0.03% of this catalyst. Both electron-rich and sterically hindered substrates are welcome in this protocol.404... 

Direct C-Harylation of purines in position 8 by diverse aryl iodides has been achieved with Pd catalysis in the presence of Cul and CS2CO3. The methodology is general and efficient and was applied in the consecutive regioselective synthesis of 2,6,8-trisubstituted purines bearing three different C-substituents in combination with two cross-coupling reactions... 

Bromoalkynes also couple with vinylstannanes readily to result in enynes. Synthesis of protected enynals via cross-coupling of vinylstannanes with 1-bromoalkynes in the presence of a catalytic amount of Pd(II) has been reported (equation 143)252. Hiyama and coworkers extended the Stille methodology for sequential three-component coupling of trimethylstannyl(trimethylsilyl)acetylene with a vinyl iodide in the first step and cross-coupling of the intermediate trimethylsilylethyne with another alkenyl iodide in the presence of tris(diethylamino)sulphonium trimethyldifluorosilicate in the second step to generate a dienyne (equation 144)253. Both steps occur under palladium catalysis, in one-pot, to result in stereodefined l,5-dien-3-ynes. 

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