The 1,2-diamine motif is widely present in natural products, pharmaceutical compounds, and catalysts used in asymmetric synthesis. The simultaneous introduction of two amino groups across an alkene feedstock is an appealing yet challenging approach for the synthesis of 1,2-diamines, primarily due to the inhibitory effect of the diamine products to transition metal catalysts and the difficulty in controlling reaction diastereoselectivity and regioselectivity. Herein we report a scalable electrocatalytic 1,2-diamination reaction that can be used to convert stable, easily available aryl alkenes and sulfamides to 1,2-diamines with excellent diastereoselectivity. Monosubstituted sulfamides react in a regioselective manner to afford 1,2-diamines bearing different substituents on the two amino groups. The combination of an organic redox catalyst and electricity not only obviates the use of any transition metal catalyst and oxidizing reagent, but also ensures broad reaction compatibility with a variety of electronically and sterically diverse substrates.
The 1,2-diamine motif is prevalent
in natural products, small-molecule
pharmaceuticals, and catalysts for asymmetric synthesis. Transition
metal catalyzed alkene diazidation has evolved to be an attractive
strategy to access vicinal primary diamines but remains challenging,
especially for practical applications, due to the restriction to a
certain type of olefins, the frequent use of chemical oxidants, and
the requirement for high loadings of metal catalysts (1 mol % or above).
Herein we report a scalable Cu-electrocatalytic alkene diazidation
reaction with 0.02 mol % (200 ppm) of copper(II) acetylacetonate as
the precatalyst without exogenous ligands. In addition to its use
of low catalyst loading, the electrocatalytic method is scalable,
compatible with a broad range of functional groups, and applicable
to the diazidation of α,β-unsaturated carbonyl compounds
and mono-, di-, tri-, and tetrasubstituted unactivated alkenes.
Dehydrogenative annulation reactions are among the most straightforward and efficient approach for the preparation of cyclic structures. However, the applications of this strategy for the synthesis of saturated heterocycles have been rare. In addition, reported dehydrogenative bond-forming reactions commonly employ stoichiometric chemical oxidants, the use of which reduces the sustainability of the synthesis and brings safety and environmental issues. Herein, we report an organocatalyzed electrochemical dehydrogenative annulation reaction of alkenes with 1,2- and 1,3-diols for the synthesis of 1,4-dioxane and 1,4-dioxepane derivatives. The combination of electrochemistry and redox catalysis using an organic catalyst allows the electrosynthesis to proceed under transition metal- and oxidizing reagent-free conditions. In addition, the electrolytic method has a broad substrate scope and is compatible with many common functional groups, providing an efficient and straightforward access to functionalized 1,4-dioxane and 1,4-dioxepane products with diverse substitution patterns.
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