1-stannyl-1-alkene 1-alkyne

A synthetically useful and convenient method for the B(C6F5)3-catalyzed hydro-stannylation of alkynes with tributyltin hydride, prepared in situ from easily handled and inexpensive chlorostannane and hydrosilane, has been developed by Yamamoto and his colleagues [155]. The hydrostannylation of monosubstituted alkynes proceeds in a regiospecific manner to give the /3-hydrostannylation products exclusively (Eq. 100). The reaction is trans stereoselective. This method can also be applied to the hydrostannylation of allenes and alkenes (Eqs 101 and 102). 

Hydrotitanation of 1-silyl- and I-stannyl-1-alkynes leads to P-silyl (or p-stannyOalkenyltitanates, thus showing opposite regioselectivity to other related processes (hydroboration, hydroalumination, hydromagnesiation, hydrotitanation, hydrozincation, hydrozirconation).Well-defined alkenes are obtained on further reaction of the alkenylti-tanates, for example, with allylic carbonates an 8 2 displacement occurs to afford 1,4-di-... 

Complexes of internal alkynes of general formula Pd(7] -alkyne)(PR3)2 or Pd( 7 -alkyne)(diphos) have been reported, often prepared in the course of palladium-catalyzed reactions and other processes. Thus, most of them have been synthesized by decomposition of Pd(ii) complexes in the presence of the alkyne as shown in Equations (20) and (21). Insertion into a Pd-E bond and reductive elimination generates the silylated or stannylated alkene and Pd(0), which is trapped by the alkyne in excess. 

The same stannyl phosphine will also add to both terminal and non-terminal alkynes32, giving stannyl-substituted alkenes. In the case of terminal alkynes E- and Z-isomers are formed, with a mixture of the two possible regioisomers. Total yields are 60-80%, with 60-90% preference for the E-isomer, depending on the substituents on the alkyne, although exact experimental details are not given (reaction 24). 

Mechanistically, a (silyl)(stannyl)palladium initially formed undergoes regioselective silylpalladation to the alkyne moiety of the enyne (Scheme 66). Then, two possible pathways are conceivable for addition to the alkene moiety, that is, stannylpalladation and carbopalladation. It has not been established that which pathway operates. 

Each of the syntheses of seychellene summarized in Scheme 20 illustrates one of the two important methods for generating vinyl radicals. In the more common method, the cyclization of vinyl bromide (34) provides tricycle (35).93 Because of the strength of sjp- bonds to carbon, the only generally useful precursors of vinyl radicals in this standard tin hydride approach are bromides and iodides. Most vinyl radicals invert rapidly, and therefore the stereochemistry of the radical precursor is not important. The second method, illustrated by the conversion of (36) to (37),94 generates vinyl radicals by the addition of the tin radical to an alkyne.95-98 The overall transformation is a hydrostannylation, but a radical cyclization occurs between the addition of the stannyl radical and the hydrogen transfer. Concentration may be important in these reactions because direct hydrostannylation of die alkyne can compete with cyclization. Stork has demonstrated that the reversibility of the stannyl radical addition step confers great power on this method.93 For example, in the conversion of (38) to (39), the stannyl radical probably adds reversibly to all of the multiple bond sites. However, the radicals that are produced by additions to the alkene, or to the internal carbon of the alkyne, have no favorable cyclization pathways. Thus, all the product (39) derives from addition to the terminal alkyne carbon. Even when cyclic products might be derived from addition to the alkene, followed by cyclization to the alkyne, they often are not found because 0-stannyl alkyl radicals revert to alkenes so rapidly that they do not close. 

The addition of Cp2Zr(H)Cl, known as the Schwartz reagent [30], to different alkenes and alkynes is known to be a facile process [31]. Therefore, the hydrozirconation of a variety of readily available enynes 12 is among the first methods developed for the stereoselective preparation of dienyl zirconium reagents 13. This process is both completely chemo- and regioselective with a syn addition of the zirconium hydride across the alkyne [32] (Scheme 5). From the same intermediate, the Zr atom can be isomerized in its internal position such as in 15 via a zirconacyclopropene intermediate 14. Moreover, the addition of trimethylstannyl chloride to 14 led to the stannylated dienyl zirconocene 16 [33] (Scheme 5). 

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