Complexed terminal alkynes, base

Reactions of Complexed Terminal Alkynes with Base... 

The stoichiometric insertion of terminal alkenes into the Cu-B bond of the (NHC)Cu-B(cat) complex, and the isolation and full characterisation of the p-boryl-alkyl-copper (I) complex has been reported. The alkyl complex decomposes at higher temperatures by P-H elimination to vinylboronate ester [67]. These data provide experimental evidence for a mechanism involving insertion of alkenes into Cu-boryl bonds, and establish a versatile and inexpensive catalytic system of wide scope for the diboration of alkenes and alkynes based on copper. 

Other ruthenium-based catalysts are also active. Ruthenium dichloride-cymene complex is stereoselective for formation of the Z-vinyl silanes from terminal alkynes. 

A palladium catalyst with a less electron-rich ligand, 2,2-dipyridyl-methylamine-based palladium complexes (4.2), is effective for coupling of aryl iodides or bromides with terminal alkynes in the presence of pyrrolidine and tetrabutylammonium acetate (TBAB) at 100°C in water.37 However, the reactions were shown to be faster in NMP solvent than in water under the reaction conditions. Palladium-phosphinous acid (POPd) was also reported as an effective catalyst for the Sonogashira cross-coupling reaction of aryl alkynes with aryl iodides, bromides, or chlorides in water (Eq. 4.18).38... 

The benzoquinone 66 is similarly prepared by the regioselective cycloaddition of 64, derived from 63. The cyclization reaction is based on the electronic effect of the substituent of 65 [34]. The maleoylcobalt complex 67, substituted by PPh3, is unreactive towards terminal alkynes. The reaction course is altered... 

Alkynylcoppers constitute a class of compounds relevant to several synthetic organic reactions,47 where they have been proposed as key intermediates. The interest in this area has supposed that the number of structurally characterized alkynylcopper complexes has considerably expanded in the last few years. The most common route toward alkynylcoppers is based on the reaction of a terminal alkyne with a copper source, either a salt or an organocopper compound (Equations (8) and (9)). 

Computational and catalytic studies of the hydrosilylation of terminal alkynes have been very recently reported, with the use of [ Ir( r-Cl)(Cl)(Cp ) 2] catalyst to afford highly stereoselectively P-Z-vinylsilanes with high yields (>90%) [35]. B-isomers can be also found among the products, due to subsequent Z —> E isomerization under the conditions employed. The catalytic cycle is based on an lr(lll)-lr(V) oxidahve addition and direct reductive elimination of the P-Z-vinylsilane. Other iridium complexes have been found to be active in the hydrosilylation of phenylacetylene and 1-alkynes for example, when phenylacetylene is used as a substrate, dehydrogenative silylation products are also formed (see Scheme 14.5 and Table 14.3). 

Metal acetylacetonates quench triplet species generated by flash photolysis of aromatic ketones and hydrocarbons.330-333 More recently, these reactions have been studied from a synthetic standpoint. Triplet state benzophenone sensitizes photoreduction of Cu(MeCOCHCOMe)2 by alcohols to give black, presumably polymeric, [Cu(MeCOCHCOMe)] . This reacts with Lewis bases to provide complexes of the type CuL2(MeCOCHCOMe) (L = bipyridyl/2, ethylenediamine/2, carbon monoxide, Ph3P). Disubstituted alkynes yield Cu(C2 R2 XMeCOCHCOMe) but terminal alkynes form CuQR acetylides.334 The bipyridyl complex of copper(I) acetylacetonate catalyzes the reduction of oxygen to water and the oxidation of primary and secondary alcohols to aldehydes and ketones.335... 

Rapid development of this area followed the discovery of routes to these complexes, either by ready conversion of terminal alkynes to vinylidene complexes in reactions with manganese, rhenium, and the iron-group metal complexes (11-14) or by protonation or alkylation of some metal Recent work has demonstrated the importance of vinylidene complexes in the metabolism of some chlorinated hydrocarbons (DDT) using iron porphyrin-based enzymes (15). Interconversions of alkyne and vinylidene ligands occur readily on multimetal centers. Several reactions involving organometallic reagents may proceed via intermediate vinylidene complexes. 

In 1999, Carreira identified Zn(II) as a metal that, like Ag(I) and Cu(I), is capable of effecting the metalation of terminal acetylenes under mild conditions. Thus, treatment of terminal alkynes with Zn(OTf)2 and NEt3 at room temperature led to the formation of zinc alkynylides (Eq. 4). The zinc salt and the amine base work in synergy to weaken the acetylenic proton, with the acetylene undergoing complexation to the Zn(II) center and the base effecting subsequent deprotonation (Fig. 1) [11]. 

Based on these results, conditions for alkyl-Sonogashira coupling reactions were developed. Primary alkyl halides reacted with terminal alkynes catalyzed by 5 mol% of complex 24a and Cul in the presence of substoichiometric amounts of Nal for bromides or Bu4NI for alkyl chlorides (entry 29) [73]. The latter serves to catalyze the in situ generation of more reactive alkyl iodides under the reaction conditions. The internal alkyne products were isolated in 57-89% yield. The Sonogashira coupling can also be combined to the Kumada reaction described above. a,o)-Chloroalkyl bromides underwent the Kumada coupling first selectively... 

In the presence of a base (Et3N) the ruthenium vinylidene complex RuCl(Cp )(PPh3)(=C=CHPh) promotes the selective cross-coupling of a bulky terminal alkyne with internal alkynes at room temperature to yield functionalized enynes (Eq. 10) [77]. 

Ruthenium complexes are known to be generally less reactive in hydrosilylation reactions when compared with platinum and rhodium ones. However, very selective ruthenium-based catalytic systems have been recently developed. The hydrosilylation of terminal alkynes generally tends to proceed through cis addition, resulting in trans adducts as the main products. 

The monosubstituted vinylidene complexes are readily deprotonated with a variety of mild bases (e.g., MeO-, C032 ), and this reaction constitutes the most convenient route to ruthenium acetylide complexes. Experimentally the deprotonation is most easily achieved by passing the vinylidene complex through basic alumina. Addition of a noncomplexing acid (e.g., HPF6) to the acetylide results in the reformation of the vinylidene complex [Eq. (66)]. Reaction of 1 and terminal alkynes such as phenylacetylene in methanol followed by the addition of an excess of... 

The coupling of terminal alkynes with aryl or vinyl halides under palladium catalysis is known as the Sonogashira reaction. This catalytic process requires the use of a palladium(0) complex, is performed in the presence of base, and generally uses copper iodide as a co-catalyst. One partner, the aryl or vinyl halide, is the same as in the Stille and Suzuki couplings but the other has hydrogen instead of tin or boron as the metal to be exchanged for palladium. 

Complexes of stoichiometry Co2(CO)g(RC2SiMe3) can be treated with base to form the terminal alkyne complexes Co2(CO)g(RC2H) (69) and treatment of the complexes Co2(CO)g(RC2SnMeg) (R = H or tert-Bu), with MeCOCl and AICI3 gives Co2(CO)g(RC2COMe) (42). 

An AuCl,-catalyzed intramolecular reaction between 2-methylfuran and a terminal alkyne to produce a phenol was the key step in the synthesis of jungianol and cpr-jungianol <03CEJ4339>. This reaction could also be catalyzed by PtClj. Based on density functional theory calculations and on the trapping of certain interme ates die mechanism was proposed to involve the cyclopropyl platinacarbene complex shown below as a key intermediate <03JA5757>. 

Recently, new types of ruthenium catalyst precursors that perform the Markovnikov addition of carboxylic acids to terminal alkynes have been developed. The most representative examples are [RuCl2(p-cymene)]2/P(furyl)3/base [50], Ru-vinylidene complexes such as RuCl2(PCy3)2(=C=CHt-Bu), RuCl2(PCy3)(bis(mesityl)imidazolyli-dene)(=C=CHf-Bu), [RuCl(L)2(=C=CHt-Bu)]BF4 [51], and the ruthenium complexes shown in Figure 8.1 [52-54]. 

One exception to this exclusion of late transition metals may be copper. CuH—MgXa complexes, prepared in situ from MgH2/CuX or from NaH/CuX/MgX2, react with terminal alkynes to give alke-nylcopper species. So far, these have only been used as sources for dialkenyl-coupling products, as in equation (54), but there is no obvious reason why other copper-based procedures should not be accessible, as was found for alkenylcopper obtained by transmetallation from Zr (Section 3.9.3.4.2). Al-kylcopper cannot be made by hydrometallation (nor by transmetallation), as CuH does not add to alkenes, except for special ones such as enones. ... 

---