Methodology Study of N-deacetylation of 4-acetamido-perfluoroalkylbenzenesulfonimide

Abban, Grace

01 August 2015

In order to improve the synthetic route for diazonium perfluoroalkyl benzenesulfonylimide (PFSI) zwitterionic monomers, N-deacetylation of the coupling product was proposed to replace the reduction of aromatic amine intermediates. A series of hydrolysis methods, such as acid and base catalyzed refluxing, were explored for the N-deacetylation to obtain the PFSI aromatic amine. Factors such as temperature, concentration of acid/base and the time needed for the reaction to take place were investigated in an attempt to optimize the reaction condition. The basic hydrolysis was preferred since it was expected to carry out the N-deacetylation and debromination in one batch reaction. N-deacetylation in base at high concentrations was successful, however, side reaction of the perfluorovinyl ether occurred. It was discovered that the best N-deacetylation method is to reflux/sonicate the coupling product with acid in methanol for six hours. The intermediates and purified products were characterized with 1HNMR, 19FNMR, GC-MS and IR.

N-deacetylation

Chemistry

Physical Sciences and Mathematics

Synthesis of a 4-(Trifluoromethyl)-2-Diazonium Perfluoroalkyl Benzenesuflonylimide (PFSI) Zwitterionic Monomer for Proton Exchange Membrane Fuel Cell

Nworie, Chimaroke

01 May 2014

In order to achieve a more stable and highly proton conducting membrane that is also cost effective, the perfluoroalkyl benzenesulfonylimides (PFSI) polymers are proposed as electrolyte for Proton Exchange Membrane Fuel Cells. 4-(trifluoromethyl)-2-diazonium perfluoro-3, 6-dioxa-4-methyl-7-octene benzenesulfonyl imide (I) is synthesized from Nafion monomer via a 5-step schematic reaction at optimal reaction conditions. This diazonium PFSI zwitterionic monomer can be further subjected to polymerization. The loss of the diazonium N2+ functional group in the monomer is believed to form the covalent bond between the PFSI polymer electrolyte and carbon electrodes support. All the intermediates and final products were characterized using 1H NMR, 19F NMR and IR spectrometry.

Organic Chemistry

Diazonium (Perfluoroalkyl) Arylsulfonylimide Zwitterionic Monomer Analogues: Effective Synthesis and Thermal Stability

Mei, Hua, Nworie, Chimaroke, Abban, Grace, Alayyaf, Abdulmajeed, MacCloud, Rebecca

09 February 2016

It is very promising to introduce diazonium moiety into Nafion monomer based Diazonium (Perfluoroalkyl) Arylsufonylimide (PFSI) monomers for further polymerization and chemical grafting onto carbon electrodes as innovative electrolyte materials in the Proton Exchange Membrane (PEM) fuel cells. The PFSI polymers, more proton conductive and stable at high temperatures, can dramatically increase the stability and lifetime of the PEM fuel cells, compared to widely used perfluorosulfuric acid (PFSA) polymers. This paper presents such a straightforward methodology to optimally construct a new nafion based diazonium PFSI monomer analogue, 2-diazonium 4-(trifluoromethyl) perfluoro-3, 6-dioxa-4-methyl-7-octene benzenesulfonylimide II. New approaches have been investigated to dramatically increase the percent yield for another monomer I, 4-diazonium perfluoro-3, 6-dioxa-4-methyl-7-octene benzenesulfonylimide. The thermal stability of the two monomer analogues then have been measured and compared. Another monomer analogue, 4-diazonium-3-fluoro perfluoro-3, 6-dioxa-4-methyl-7-octene benzenesulfonylimide III, has been attempted and discussed.

fuel cells

N-deacetylation

proton exchange membrane

Chemistry