Synthesis of acyl fluorides through deoxyfluorination of carboxylic acids.

A direct deoxyfluorination of carboxylic acids by utilizing inorganic potassium fluoride (KF) as a safe and inexpensive fluoride source has been developed. Both aryl carboxylic acids and cinnamyl carboxylic acids could be efficiently transformed into valuable acyl fluorides in moderate to high yields with good functional group tolerance. A scale-up reaction could be carried out smoothly under solvent-free conditions, which further demonstrated the practicality of this reaction in organic synthesis.

Metal-free highly chemo-selective bisphosphorylation and deoxyphosphorylation of carboxylic acids.

Carboxylic acids are readily available in both the natural and synthetic world. Their direct utilization for preparing organophosphorus compounds would greatly benefit the development of organophosphorus chemistry. In this manuscript, we describe a novel and practical phosphorylating reaction under transition metal-free reaction conditions that can selectively convert carboxylic acids into the P-C-O-P motif-containing compounds through bisphosphorylation, and the benzyl phosphorus compounds through deoxyphosphorylation. This strategy provides a new route for carboxylic acid conversion as the alkyl source, enabling highly efficient and practical synthesis of the corresponding value-added organophosphorus compounds with high chemo-selectivity and wide substrate scope, including the late modification of complex APIs (active pharmaceutical ingredients). Moreover, this reaction also indicates a new strategy for converting carboxylic acids into alkenes by coupling this work and the subsequent WHE reaction with ketones and aldehydes. We anticipate that this new mode of transforming carboxylic acids will find wide application in chemical synthesis.

Synthesis of dihydropyrroles from in situ-generated zwitterions via Rh2(adc)4/TBAI dual catalysis.

Triggered by formation of α-imino carbene, the regioselective synthesis of dihydropyrroles was achieved via a cascade 1,3-sulfinate migration/annulation. The sulfinate group was converted into sulfone during the group migration, and a stable anion bearing two electron-withdrawing groups was thus formed. The addition of a catalytic amount of iodide is believed to assist the cleavage of the C-O bond, and the formation of a more stable carbocation. Thermodynamic product dihydropyrroles were produced efficiently rather than kinetic product cyclopropanes. This dual catalysis system would afford chemists a new strategy to control the annulation selectivity of zwitterions bearing multiple reactive sites and may be employed in flexible and divergent synthesis of different ring systems.