We have developed a photoinduced copper-catalyzed alkylation of terminal alkynes with primary, secondary, or tertiary alkyl iodides as electrophiles. The reaction has a broad substrate scope and can be successfully performed in the presence of ester, nitrile, aryl halide, ketone, sulfonamide, epoxide, alcohol, and amide functional groups. The alkylation is promoted by blue light (λ≈450 nm) and proceeds at room temperature in the absence of any additional metal catalysts. The use of a terpyridine ligand is essential for the success of the reaction and is shown to prevent photoinduced copper-catalyzed polymerization of the starting materials.
Alkenes are an important class of compounds common among biologically active molecules and often used as intermediates in organic synthesis. Many alkenes exist in two stereoisomeric forms (E and Z), which have different structures and different properties. The selective formation of the two isomers is an important synthetic goal that has long inspired the development of new synthetic methods. However, the efficient synthesis of diastereopure, thermodynamically less stable, Zalkenes is still challenging. Here, we demonstrate an efficient synthesis of diastereopure Z-alkenes (Z:E > 300:1) through a silver-catalyzed hydroalkylation of terminal alkynes, using alkylboranes as coupling partners. We also describe the exploration of the substrate scope, which reveals the broad functional group compatibility of the new method. Preliminary mechanistic studies suggest that a 1,2-metallate rearrangement of the silver borate intermediate is the key step responsible for the stereochemical outcome of the reaction.
This
paper describes a detailed mechanistic study of the silver-catalyzed
Z-selective hydroalkylation of terminal alkynes. Considering the established
mechanistic paradigms for Z-selective hydroalkylation
of alkynes, we explored a mechanism based on the radical carbometalation
of alkynes. Experimental results have provided strong evidence against
the initially proposed radical mechanism and have led us to propose
a new mechanism for the Z-selective hydroalkylation
of alkynes based on boronate formation and a 1,2-metalate shift. The
new mechanism provides a rationale for the excellent Z-selectivity
observed in the reaction. A series of stoichiometric experiments has
probed the feasibility of the proposed elementary steps and revealed
an additional role of the silver catalyst in the protodeboration of
an intermediate. Finally, a series of kinetic measurements, KIE experiments,
and competition experiments allowed us to identify the turnover limiting
step and the resting state of the catalyst. We believe that the results
of this study will be useful in the further exploration and development
of related transformations of alkynes.
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