Decarboxylation of fatty acids by ternary zinc cationic complexes studied by mass spectrometry and theoretical calculations

Abstract

We have shown that fatty acids can be decarboxylated in the gas phase via collision-induced dissociation (CID) of ternary zinc complexes of the general formula [(L)Zn(OOCR)]+, where RC3H7, C6H13, C7H15, C17H35, C17H33, C17H31 and L = 1,10-phenanthroline or 2,2′:6′,2″-terpyridine. These complexes were formed by electrospray ionization of a solution mixture of zinc(II) salt, fatty acid, and the ligand. Two pathways were mapped for the resulting [(L)ZnR]+ organozinc ion: i) a gas-phase ion-molecule reaction with a neutral carboxylic acid R’COOH in the linear quadrupole ion trap resulted in the production of the alkane RH and formation of [(L)Zn(OOCR’)]+; ii) a second CID stage produced an alkene and the ion [(L)ZnH]+ which underwent a subsequent ion-molecule reaction with R’COOH to form [(L)Zn(OOCR’)]+ ion accompanied by the loss of H2. In the case of RR’ = C3H7 (butyric acid), both processes presented formal catalytic cycles with the overall equations C3H7COOHC3H8+ CO2 or C3H7COOHC3H6 + H2+ CO2. Theoretical DFT calculations provided the energetics of reactants/products as well as transition state energies and were in agreement with the experimental data. The work identifies Zn as a potential catalyst for deoxygenation of fatty acid with no fragmentation of the alkyl chain.