A series of easily prepared, phosphine-ligated palladium precatalysts based on the 2-aminobiphenyl scaffold have been prepared. The role of the precatalyst-associated labile halide (or pseudohalide) in the formation and stability of the palladacycle has been examined. It was found that replacing the chloride in the previous version of the precatalyst with a mesylate leads to a new class of precatalysts with improved solution stability and that are readily prepared from a wider range of phosphine ligands. The differences between the previous version of precatalyst and that reported here are explored. In addition, the reactivity of the latter is examined in a range of C-C and C-N bond forming reactions.
The direct CH functionalization of heterocycles has become an increasingly valuable tool in modern drug discovery. However, the introduction of small alkyl groups, such as methyl, by this method has not been realized in the context of complex molecule synthesis since existing methods rely on the use of strong oxidants and elevated temperatures to generate the requisite radical species. Herein, we report the use of stable organic peroxides activated by visible-light photoredox catalysis to achieve the direct methyl-, ethyl-, and cyclopropylation of a variety of biologically active heterocycles. The simple protocol, mild reaction conditions, and unique tolerability of this method make it an important tool for drug discovery.
Asymmetric hydrogenation of alkenes is one of the most widely used methods for the preparation of single enantiomer compounds, especially in the pharmaceutical and agrochemical industries. For more than four decades, precious metal complexes containing rhodium, iridium, and ruthenium have been predominantly used as catalysts. Here, we report rapid evaluation of libraries of chiral phosphine ligands with a set of simple cobalt precursors. From these studies, base metal precatalysts have been discovered for the hydrogenation of functionalized and unfunctionalized olefins with high enantiomeric excesses, demonstrating the potential utility of more earth-abundant metals in asymmetric hydrogenation.
We describe the development of (η3-1-tBu-indenyl)2(μ-Cl)2Pd2, a
versatile precatalyst scaffold for Pd-catalyzed cross-coupling. Our
new system is more active than commercially available (η3-cinnamyl)2(μ-Cl)2Pd2 and is compatible with a range of NHC and phosphine ligands. Precatalysts
of the type (η3-1-tBu-indenyl)Pd(Cl)(L)
can either be isolated through the reaction of (η3-1-tBu-indenyl)2(μ-Cl)2Pd2 with the appropriate ligand or generated in situ, which offers
advantages for ligand screening. We show that the (η3-1-tBu-indenyl)2(μ-Cl)2Pd2 scaffold generates highly active systems for a number of
challenging cross-coupling reactions. The reason for the improved
catalytic activity of systems generated from the (η3-1-tBu-indenyl)2(μ-Cl)2Pd2 scaffold compared to (η3-cinnamyl)2(μ-Cl)2Pd2 is that inactive PdI dimers are not formed during catalysis.
Although
the past 15 years have witnessed the development of sterically bulky
and electron-rich alkylphosphine ligands for palladium-catalyzed cross-couplings
with aryl chlorides, examples of palladium catalysts based on either triarylphosphine or bidentate phosphine ligands for efficient room temperature cross-coupling
reactions with unactivated aryl chlorides are rare. Herein we report
a palladium catalyst based on NiXantphos, a deprotonatable
chelating aryldiphosphine ligand, to oxidatively add unactivated
aryl chlorides at room temperature. Surprisingly, comparison of an
extensive array of ligands revealed that under the basic reaction
conditions the resultant heterobimetallic Pd–NiXantphos catalyst
system outperformed all the other mono- and bidentate ligands in a
deprotonative cross-coupling process (DCCP) with aryl chlorides. The
DCCP with aryl chlorides affords a variety of triarylmethane products,
a class of compounds with various applications and interesting biological
activity. Additionally, the DCCP exhibits remarkable chemoselectivity
in the presence of aryl chloride substrates bearing heteroaryl groups
and sensitive functional groups that are known to undergo 1,2-addition,
aldol reaction, and O-, N-, enolate-α-,
and C(sp2)–H arylations. The advantages and importance
of the Pd–NiXantphos catalyst system outlined herein make it
a valuable contribution for applications in Pd-catalyzed arylation
reactions with aryl chlorides.
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