Synthetic
organic electrosynthesis has grown in the past few decades
by achieving many valuable transformations for synthetic chemists.
Although electrocatalysis has been popular for improving selectivity
and efficiency in a wide variety of energy-related applications, in
the last two decades, there has been much interest in electrocatalysis
to develop conceptually novel transformations, selective functionalization,
and sustainable reactions. This review discusses recent advances in
the combination of electrochemistry and homogeneous transition-metal
catalysis for organic synthesis. The enabling transformations, synthetic
applications, and mechanistic studies are presented alongside advantages
as well as future directions to address the challenges of metal-catalyzed
electrosynthesis.
A user-friendly approach is presented to sidestep the venerable Grignard addition to unactivated ketones to access tertiary alcohols by reversing the polarity of the disconnection. In this work a ketone instead acts as a nucleophile when adding to simple unactivated olefins to accomplish the same overall transformation. The scope of this coupling is broad as enabled using an electrochemical approach, and the reaction is scalable, chemoselective, and requires no precaution to exclude air or water. Multiple applications demonstrate the simplifying nature of the reaction on multistep synthesis, and mechanistic studies point to an intuitive mechanism reminiscent of other chemical reductants such as SmI 2 (which cannot accomplish the same reaction).
This Article describes the development of a base-free, nickel-catalyzed decarbonylative coupling of carboxylic acid fluorides with diboron reagents to selectively afford aryl boronate ester products. Detailed studies were conducted to assess the relative rates of direct transmetalation between aryl boronate esters and diboron reagents and a bisphosphine nickel(aryl)(fluoride) intermediate. These investigations revealed that diboron reagents undergo transmetalation with this Ni(aryl)(fluoride) intermediate at rates significantly faster than their aryl boronate ester congeners. Furthermore, the reactivity of both boron reagents toward transmetalation is enhanced with increasing electrophilicity of the boron center. These mechanistic insights were leveraged to develop a catalytic decarbonylative borylation of acid fluorides that proved applicable to a variety of (hetero)aryl carboxylic acid fluorides as well as diverse diboron reagents. The acid fluorides can be generated in situ directly from carboxylic acids. Furthermore, the mechanistic studies directed the identification of various airstable Ni pre-catalysts for this transformation.
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