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An original concept for catalytic electrochemical dehydration has enabled a suite of acid substitutions, including amidation, esterification, and thioesterification, through a linchpin anhydride formed in situ. By avoiding stoichiometric dehydrating agents, this method addresses a leading challenge in organic synthesis and green chemistry. It also proceeds without acid additives at room temperature, accesses a diverse range of product structures, is easily scaled, and enabled the first example of catalytic peptide coupling at room temperature. 

An electrochemical coupling between carboxylic acids and penta uorophenol (PFP–OH) to access synthetically versatile penta uorophenyl (PFP) esters has been developed. Novel reactivity of PFP–OH was turned on by modulating its oxidation state, leveraging both its native O-nucleophilicity and its latent, oxidation-induced C-electrophilicity to promote a unique cascade of nucleophilic aromatic and acyl substitutions. Its esteri cation with acids was thus achieved for the rst time without exogenous dehydrating agents. The acidity of PFP–OH and the oxidizability of its conjugate base enabled its mild and selective activation via deprotonation–oxidation, readily affording PFP esters that are useful in many applications (peptide synthesis, chemical biology, etc.) and that contain redox-sensitive functional groups. Finally, we verified in a unified forum that an amino-acid-derived PFP ester can be converted into a range of acyl-substitution products while retaining key stereochemical information, and we demonstrated that PFP esters have excellent stability to hydrolysis, comparing favorably even to N-hydroxysuccinimidyl (NHS) esters. 

A free-radical approach featuring an intramolecular aryl migration has significantly expanded the scope for the alkyl–(hetero)arylation of simple olefins. It was also leveraged as the key step in a new synthesis of a recently approved pharmaceutical.