Fluorescence probe techniques (FPT) have been used to obtain curing profiles for the polymerization of a model monomer, triethylene glycol diacrylate (TEGDA). A number of new chromophore ammonium salt triphenylbutyl and tetraphenylborates differing only in the structure of the ammonium salt moiety have been used as photoinitiators. The borates were chosen for study so that a comparison of their initiation efficiency would reveal information about the relative activity of possible initiating species produced upon borate photodecomposition. The results support our previous postulate that an R-aminoalkyl radical formed immediately after unimolecular decomposition from the tetraphenylborates is the most effective initiating species and that R-aminoalkyl radicals significantly increase the photoinitiator efficiency of triphenylbutylborates as well. The importance of other radicals to the initiation step is also discussed.
IntroductionThe photochemistry of tetrasubstituted borate salts has attracted substantial recent research interest. [2][3][4][5][6][7][8] Triphenylbutylborates have been studied most extensively, and the butyl radical formed when they are oxidized has been found to be the dominant initiating species for radical polymerization. 3,7-10 Interestingly, tetraphenylborates paired with a similar cationic partner have been observed to have similar initiating efficiencies. 11-13 Tetraphenylborates, when oxidized, are often prone to back electron transfer. Since phenyl radicals are produced from tetraphenylborates upon oxidation inefficiently, if at all, we have surmised that other initiating species must account for the efficiency of tetraarylborate salts. In our most recent work R-aminoalkyl, phenyl, and p-benzoylbenzyl radicals were trapped by methyl methacrylate when benzophenonemethylenetributylammonium triphenylbutylborate was photolyzed in its presence in solution. 14 Fluorescence probe techniques (FPT) have been recently introduced to measure and compare photoinitiator efficiencies. 12,13,15,16 FPT allow one to measure the polymerization kinetics from relative conversion data collected during the polymerization of systems that are similar. These methods are particularly useful for the evaluation of initiators that are similar in structure and for optimizing their performance. The possibility of collecting data over short time intervals (<1 s) makes the analysis simple and accurate. Several borates differing in the ammonium salt but possessing benzophenone and acetonaphthone chromophores have been chosen for the current work.