The dehydration behavior of LiOH-modified Mg(OH)₂ (LiOH/Mg(OH)₂), as a new chemical heat storage material, was investigated. Structural analysis of LiOH/Mg(OH)₂ was carried out using an X-ray diffraction (XRD) meter. The profile of the dehydration reaction of LiOH/Mg(OH)₂ was observed to analyze the dehydration kinetics of the LiOH/Mg(OH)₂ samples. The XRD patterns of the LiOH/Mg(OH)₂ samples shifted toward higher angles than that of Mg(OH)₂. This indicated that the lattice parameter might have changed and lattice defects such as oxygen vacancies might have been generated on the surface of Mg(OH)₂. The rate of the dehydration reaction increased as the amount of added LiOH increased; therefore, LiOH/Mg(OH)₂ could be a potential chemical heat storage material. We concluded that LO20 (Mg(OH)₂ containing 20 mol% LiOH) was the combination with the most optical mixing mole ratio. This result was determined by analyzing the dehydration activation energy values. When the dehydration reactions of the LiOH/Mg(OH)₂ samples were considered to be first-order reactions, the calculated mole fraction of Mg(OH)₂ could not be reproduced. However, the calculated mole fractions of Mg(OH)₂ were in agreement with those measured considering the reactions to be zero- and first-order reactions. Therefore, the kinetics of the dehydration reaction of the LiOH/Mg(OH)₂ samples included both zero- and first-order reactions.