Catalina Ferrer

Gold(I)-Catalyzed Intermolecular Addition of Carbon Nucleophiles to 1,5- and 1,6-Enynes

Gold(I)-catalyzed addition of carbon nucleophiles to 1,6-enynes gives two different type of products by reaction at the cyclopropane or at the carbene carbons of the intermediate cyclopropyl gold carbenes. The 5-exo-dig cyclization is followed by most 1,6-enynes, although those bearing internal alkynes and alkenes react by the 6-endo-dig pathway. The cyclopropane versus carbene site-selectivity can be controlled in some cases by the ligand on the gold catalyst. In addition to electron-rich arenes and heteroarenes, allylsilanes and 1,3-dicarbonyl compounds can be used as the nucleophiles. In the reaction of 1,5-enynes with carbon nucleophiles, the 5-endo-dig pathway is preferred.

Gold(I)-catalysed arylation of 1,6-enynes: different site reactivity of cyclopropyl gold carbenes

Gold(I)-catalysed addition of electron-rich arenes and heteroarenes to 1,6-enynes gives two different types of products by reaction of the intermediate cyclopropyl gold carbenes at the cyclopropane or at the carbene.

Primary and Secondary Aminophosphines as Novel P-Stereogenic Building Blocks for Ligand Synthesis†

Chiral phosphine ligands are central to asymmetric metal catalysis. The effect of the majority of these ligands arises from the chirality of their backbones; however, P-stereogenic (P*) ligands have garnered renewed interest. After the decisive work of Knowles and co-workers with PAMP and DIPAMP ligands, several efficient syntheses of all-carbon P* compounds have been reported. In contrast, P* compounds that contain heteroatoms directly linked to the phosphorus center are scarce, and have found little application in catalysis. This class of substances includes secondary phosphine oxides, which exist in equilibrium with their trivalent phosphinite form. P* aminophosphines, which are the corresponding nitrogen analogues, are even more rare, as free primary aminophosphines tend to dimerize with the evolution of ammonia. However, Kolodiazhnyi et al. have reported that borane aminophosphines of type I are stable and that they can be obtained in diastereomerically pure form using 2-phenylethylamine as a chiral amine (Scheme 1). Nonetheless, type I compounds do not have any reported applications in asymmetric catalysis, nor has their hydrogenolysis been described. We envisioned that reductive cleavage of the arylethyl fragment should provide boraneprotected primary aminophosphines of type II, which would be amenable to further transformations and become useful P* building blocks in catalysis. Herein, we report the synthesis of enantiopure P-chiral primary and secondary aminophosphines (II) and diphosphinoamines (III). We began by investigating the hydrogenolysis of the known compound 1a, which contains a tert-butyl(phenyl)phosphinamine moiety (Scheme 2), under various

Phosphine–Alkene Ligands as Mechanistic Probes in the Pauson–Khand Reaction

An alkyne tetracarbonyl dicobalt complex with a chelated phosphine-alkene ligand, in which the phosphorus atom and the alkene from the ligand are attached to the same cobalt atom has been prepared, isolated, and characterized by X-ray crystallography. The complex serves as a mechanistic model for an intermediate of the Pauson-Khand (PK) reaction. Although the alkene fragment is located in an equatorial coordination site with an appropriate orientation, and, therefore, should undergo insertion, it failed to give the PK product upon either thermal or N-methylmorpholine N-oxide activation. However, a phosphine-alkene complex that contains a terminal alkene readily provided the corresponding PK product. We attribute this change in reactivity to the different ability of each olefin to undergo 1,2-insertion. These results provide further insights into the factors that govern a crucial step in the PK reaction, the olefin insertion.