Photoinduced Cu(II)-Mediated Decarboxylative Thianthrenation of Aryl and Heteroaryl Carboxylic Acids.

Abstract

Given that (hetero)aryl carboxylic acids are inexpensive materials available in a great variety from commercial and natural resources or synthesis, the strategies enabling their use as starting materials for preparing fine chemicals are highly sought after. Here we report a photoinduced Cu(II)-mediated protocol converting (hetero)aryl carboxylic acids into (hetero)aryl thianthrenium salts, high value-added building blocks that can undergo various subsequent transformations, creating an attractive two-step pathway for the divergent functionalization of these ubiquitous starting materials. The excellent compatibility of the method is shown by preparing a broad range of sterically and electronically varied (hetero)aryl thianthrenium salts, including derivatives of pharmaceuticals, such as ataluren, celecoxib, flavoxate, probenecid, repaglinide, and tamibarotene. The syntheses of 13C-labeled probenecid and bioisosteres of ataluren as well as the unconventional modifications of celecoxib and flavoxate, illustrate the synthetic potential of the strategy. Mechanistic studies are in line with a reaction occurring through a photoinduced ligand-to-metal charge transfer (LMCT) of Cu(II)-arylcarboxylates, enabling radical decarboxylative carbometallation to form arylcopper(II) intermediates that in turn react with thianthrene to form the product. Noteworthy, the susceptibility of aryl thianthrenium salts to photodegradation is overcome by a Cu(I)-driven salvage loop, which continuously intercepts the transiently formed radicals and regenerates the products.