Cure depth in photopolymerization: Experiments and theory

The depth of photocuring for a model resin system was investigated as a fun ction of photoinitiator concentration. Direct measurements of gel thickness were made from thin filins of cross-linked multifunctional rnethacrylate m onomer. The monomer, 2,2-bis{4-[2-hydroxy-3-(methacryloxy)propoxy]phenyl}pr opane, was polymerized in a solution of trichloroethylene with an ultraviol et laser light source at 325 rim. The monomer solutions were photocured usi ng varying levels of both photonic energy and photoinitiator concentration. An optimal photoinitiator concentration that maximized the gel cure depth was observed. Additionally, two regimes were shown to exist in which the sh rinkage (upon solvent removal) was minimized or maximized, A model was deve loped to probe the physics of the system. Good agreement with experiment wa s obtained, and the model may be employed to predict both the existence and location of the optimal photoinitiator concentration and the corresponding cure depth. The study showed that photoinitiator plays a significant role in controlling the quality and performance of the formed gel network, with special regard to thickness of cured layers. This has potential application to fields as diverse as industrially cured coatings and dental fillings, a nd more generally, 3-dimensional rapid prototyping techniques.