Koji pottery, a kind of low temperature color glazed pottery, is used in decorative architectural motifs on Taiwan’s traditional temples and residential buildings. Combined with the molding, glaze making and kiln-firing techniques, Koji pottery is shaped into vivid models with resplendent color and preserves the historical allusions and auspicious meanings reflecting life and religion during the early period of Taiwan. Moreover, Koji pottery bears witness to the development of craft techniques and culture. However, the lowfiring process leaves the Koji pottery fabric porous. Furthermore, most of the ancient Koji pottery works are preserved in situ and so they are always threatened by aging and weathering after being exposed to the elements for many years. For these reasons, it is urgent to protect Koji pottery works. This research strives to consolidate ancient Koji pottery using nano-calcium hydroxide. Nano-calcium hydroxide uses CaCl2 as a starting material and 2-propanol as a solvent. First, CaCl2 was dissolved in hot water flushed with nitrogen. This was then added to 2-propanol and the solid separated by centrifugation and ultrasonication. Nanocalcium hydroxide, as a colloidal solution was produced with a particle size 80~150nm. Nano-calcium hydroxide was analysed by powder XRD, Raman spectroscopy and TEM. Secondly, a vacuum drying oven was employed to condense the colloidal solution to give a calcium hydroxide concentration of 5g/L. The colloidal solution was repeatedly applied to Koji pottery samples and was neutralized by carbonating it in a carbon dioxide atmosphere (humidity 95%, temperature 50 ºC). Finally, after the curing process, Raman spectroscopy was used to characterize the in crystal structure. The results show that calcium hydroxide did not interact with SiO2 to turn into calcium silicate; instead it formed CaCO3 and the ceramic body underwent physical consolidation. The porosity and water absorption were decreased by 2% and flexural strength was increased by 7% after consolidation. This research proves that consolidation by nano-calcium hydroxide is effective in reducing porosity and water absorption and reinforcing flexural strength.