Font Size: a A A

Experimental and theoretical investigations of active center generation and mobility in cationic and free-radical photopolymerizations

Posted on:2011-11-23Degree:Ph.DType:Dissertation
University:The University of IowaCandidate:Hoppe, Cynthia CarolineFull Text:PDF
GTID:1441390002965542Subject:Engineering
Abstract/Summary:
Photopolymerization is considered an attractive alternative in many industries to traditional polymerization processes. The advantages of photopolymerization over other types of polymerization include elimination of heat sources, faster cure times, and reduction in the use of volatile organic solvents. Despite these environmental and cost-saving advantages, photopolymerizations have several limitations. Light attenuation can be a problem for systems containing pigments or fillers. The radiation source penetrates only to a shallow depth beneath the surface, limiting the thickness of strongly pigmented or filled coatings and films. Photopolymerization is also generally limited to systems with simple geometries that can be uniformly illuminated. Coatings on three-dimensional substrates, or other systems with complex geometries, are difficult to uniformly cure. These problems can be solved by "shadow cure," which is defined as the reactive diffusion of photoinitiated active centers into regions of a polymer that are unilluminated. In this contribution, the generation and subsequent spatial and temporal evolution of the active center concentrations during illumination are described using the differential equations that govern the light intensity and photoinitiator concentration for polychromatic illumination. Reactive diffusion of the active centers during the post-illumination period is characterized, and shown to result in cure of unilluminated regions. A kinetic analysis is performed by coupling the active center concentration profiles with the propagation rate equation, yielding predicted cure times that are compared with experimental results. This analysis is used for the evaluation of cationic shadow cure in pigmented photopolymerization systems, and systems with complex geometries. The extensive characterization of cationic systems is then applied to free-radical photopolymerization to examine the potential of shadow cure for active centers with much shorter lifetimes. An example of a free-radical photopolymerization system is presented in which the dimensional scales are small enough to utilize the short lifetimes of free-radical active centers for shadow cure. The results for both free-radical and cationic shadow cure indicate that the reactive diffusion of photoinitiated active centers may be used for effective cure in unilluminated regions of a photopolymer. This research will potentially allow photopolymerization to be used for applications in industries where it has never before been utilized.
Keywords/Search Tags:Photopolymerization, Active, Free-radical, Cationic, Shadow cure
Related items