In this work, a high-throughput technique for evaluating photopolymers is developed to enable simultaneous measurement of the effects of temperature in combination with exposure time. Temperature and exposure time gradients were produced in orthogonal directions on a single sample, and subsequently sampled using Fourier transform infrared (FTIR) spectroscopy. The technique developed here allows for photopolymerization kinetics to be analyzed rapidly over a large range of industrially relevant temperatures, giving insight into the role temperature and the polymer's glass transition temperature have in dictating the photopolymerization kinetics. In the 70/30 wt % hexyl acrylate and hexanediol diacrylate system, conversion in samples below the glass transition temperature (T-G) was 66 +/- 2% after 12 s, significantly lower than the 93 +/- 4% conversion at 12 s for samples polymerized at temperatures above the T-G. In addition, a thiol-ene system was analyzed to study the effect of temperature on the ene homopolymerization in allyl ether monomers, which leads to incomplete thiol conversion in stoichiometrically balanced systems. At a 60% thiol conversion, the allyl ether-ene conversion at all temperatures is 65 +/- 3% irrespective of initial formulation temperature, indicative of the homopolymerization behavior being nearly independent of temperature. (c) 2008 Wiley Periodicals, Inc.