846541-40-0Relevant articles and documents
Syntheses and synthetic applications of stannylated allylic alcohols
Kazmaier, Uli,Lucas, Simon,Klein, Manuela
, p. 2429 - 2433 (2007/10/03)
Allenyl carbinols undergo regioselective hydrostannation in the presence of MoBl3, a catalyst originally developed for the hydrostannation of alkynes, giving rise to allyl stannanes. These allyl stannanes can easily be converted into useful synthetic building blocks such as allyl iodides or vinyl epoxides.
Molybdenum-catalyzed hydrostannations of allenylcarbinols
Kazmaier, Uli,Klein, Manuela
, p. 501 - 503 (2008/09/18)
Allenylcarbinols undergo regioselective hydrostannation in the presence of MoBl3, a catalyst which was developed for the hydrostannation of propargyl alcohols and derivatives; allylstannanes are formed preferentially, which can easily be conver
C-C-Bond Formation by the Palladium-Catalyzed Cycloisomerization/Dimerization of Terminal Allenyl Ketones: Selectivity and Mechanistic Aspects
Hashmi, A. Stephen K.,Ruppert, Thorsten L.,Knoefel, Thomas,Bats, Jan W.
, p. 7295 - 7304 (2007/10/03)
The scope of the palladium-catalyzed cyclization/dimerization of terminal allenyl ketones 1 to the 2,4-disubstituted furans 3 has been investigated. Simplified and improved conditions almost exclusively provided the dimer 3, accompanied by only traces of the easily separable monomer 2. The formation of an isomer of 3, the unconjugated ketone 4, was completeley suppressed. Under these mild conditions, besides the normal functional group tolerance known for palladium-catalyzed reactions, an interesting selectivity was observed with functional groups that are known to react either in palladium-catalyzed reactions or reactions catalyzed by other transition-metals. Thus aryl halides, terminal alkynes, 1,6-enynes, and α-allenic alcohols were tolerated. In the latter example the selective reaction of only one out of two different allenes was achieved. Mechanistic investigation indicated a Pd(II)/Pd(IV)-cycle involving palladium(II)-γ-alkoxyvinylcarbene and furylpalladium(IV) hydride intermediates, although a second pathway for the formation of the dimer 3 which also involves Pd(IV)-intermediates like the 3,4-dimethylenepalladacyclopentane 23 and the 3-methylenepalladacyclobutane-like structure 15 (respectively 25) could not completely be excluded.
