Photo-crosslinking of polyethylene by mono- and diacetophenone derivatives and their precursors

Abstract

The efficiency of photochemical crosslinking of low-density polyethylene (PE) films by molecules containing one or two acetophenone groups and their precursors have been correlated with the relative rates of carbonyl group depletion under equivalent irradiation conditions. The acetophenone derivatives are found to be equally or more efficient than benzophenone as crosslinkers of PE. Because some additives are not thermodynamically equilibrated in the PE matrices and crystallize on standing at 30 °C, doped films were irradiated usually as soon as possible after their preparation. However, others were aged to determine the influence of equilibration on the efficiency of crosslinking. Thus, the effect of crystallization of some of the crosslinker additives in the PE matrices and the competition between photochemical addition of the carbonyl groups to C–H or CC bonds of the polymer were investigated. GC-MS and FTIR analyses of photoproducts from irradiation of alkanophenones bearing a γ-hydrogen atom in PE films showed that (intramolecular) Norrish Type II splitting and Yang cyclization processes proceed efficiently, and are more rapid than subsequent intermolecular hydrogen abstraction reactions by the acetophenone photoproducts.