To evaluate the effects of different curing strategies on the durability of the dual-cure resin cement/ceramic bond. Machinable ceramic blanks were cut into pairs of 3-mm-thick slices, which were then polished using wet 600-grit SiC paper. The slices were silanated using one of two ceramic priming systems: (1) Tokuso Ceramic Primer (TCP), and (2) K-etchant/Clearfil Liner Bond 2V Primer (LB2V)/Porcelain Bond Activator (PBA), and bonded with one of two dual-cure resin cements (Bistite II, Panavia F), to make four experimental groups. Each group was subjected to one of three curing strategies: (1) no light, (2) 20 s light exposure from one direction, and (3) 20 s light exposure from each of six directions. After 24 h water storage at 37°C, 0.7-mm-thick slabs were produced by serially sectioning perpendicular to the bonded interface. Immediately thereafter, and after one and six weeks of water storage, two slabs were randomly selected and sliced into beams for the microtensile bond strength (µTBS) test. Data were evaluated using Kruskal-Wallis and Wilcoxon rank tests (p 0.05), and failure modes determined using a laser-scanning confocal microscope. After priming with TCP, µTBS of Bistite II significantly increased over time when exposed to light, whereas the µTBS of the no-light group significantly decreased over time (p 0.05). After priming with TCP, µTBS of Panavia F increased over time, and after 6 weeks water storage, there were no significant differences in µTBS between the no-light and light-exposed groups (p > 0.05). Increases in µTBS were associated with increases in the number of cohesive failures in resin cement. After phosphoric acid treatment, priming with LB2V/PBA, and light exposure, µTBS of Bistite II remained stable, whereas that of Panavia F significantly reduced over time (p 0.05). The µTBS of no-light LB2V/PBA groups reduced significantly over time (p 0.05). The durability of the dual-cure resin cement/ceramic bond depends upon the multicomponent ceramic primer and the amount of light received by the resin cement.