Carbon dioxide, a primary driver of global warming, offers a promising feedstock for valuable chemical synthesis. Nonetheless, the reliance on highly pressurized canisters and specialized equipment limits its practical application in fine chemical synthesis. This study explores the innovative use of sodium bicarbonate (NaHCO3) as a safe, solid, on-demand source of CO2 under mechanochemical conditions to perform carboxylation reactions. Two applications of the practical mechanochemical syntheses using sodium bicarbonate are developed: first, the synthesis of cyclic carbamates from propargylic amines is investigated, and second, cyclic organic carbonates are derived from epoxides. The potential of this approach in the pharmaceutical industry is further showcased by demonstrating the solvent-minimized synthesis of pharmaceutically relevant molecules and introducing a 13C-labeling strategy utilizing NaH13CO3.
Mechanochemical Activation of NaHCO3: A Solid CO2 Surrogate in Carboxylation Reactions / Mele, F.; Aquilini, A.; Constantin, A. M.; Pancrazzi, F.; Righi, L.; Porcheddu, A.; Maggi, R.; Cauzzi, D. A.; Maestri, G.; Motti, E.; Capaldo, L.; Della Ca', N.. - In: CHEMSUSCHEM. - ISSN 1864-5631. - 18:14(2025). [10.1002/cssc.202500461]
Mechanochemical Activation of NaHCO3: A Solid CO2 Surrogate in Carboxylation Reactions
Mele F.;Constantin A. M.;Pancrazzi F.;Righi L.;Maggi R.;Cauzzi D. A.;Maestri G.;Motti E.;Capaldo L.;Della Ca' N.
2025-01-01
Abstract
Carbon dioxide, a primary driver of global warming, offers a promising feedstock for valuable chemical synthesis. Nonetheless, the reliance on highly pressurized canisters and specialized equipment limits its practical application in fine chemical synthesis. This study explores the innovative use of sodium bicarbonate (NaHCO3) as a safe, solid, on-demand source of CO2 under mechanochemical conditions to perform carboxylation reactions. Two applications of the practical mechanochemical syntheses using sodium bicarbonate are developed: first, the synthesis of cyclic carbamates from propargylic amines is investigated, and second, cyclic organic carbonates are derived from epoxides. The potential of this approach in the pharmaceutical industry is further showcased by demonstrating the solvent-minimized synthesis of pharmaceutically relevant molecules and introducing a 13C-labeling strategy utilizing NaH13CO3.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
