Chrysotile is a 1:1 sheet silicate mineral belonging to serpentine group. It has been highlighted studies because of uses, shapes and structural characteristics of the fibrous chrysotile. However, it was designated as Class 1 carcino-gen, so high attentions were being placed on detoxification studies of chrysotile. The objectives of this study were to investigate changes of mineralogical characteristics of chrysotile and to suggest detoxification mechanism of chrysotile by thermal decomposition. Samples for this study were obtained from LAB Chrysotile mine in Canada. The samples were heated in air in the range of 600 to 1,300°C . Changes of mineralogical characteristics such as crystal structure, shape, and chemical composition of the chrysotile fibers were examined by TG-DTA, XRD, FT-IR, TEM-EDS and SEM-EDS analyses. As a result of thermal decomposition, the fibrous chrysotile having hollow tube structure was dehydroxylated at 600-650°C and transformed to disordered chrysotile by removal of OH at the octahedral sheet (MgOH) (Dehydroxylation 1). Upon increasing temperature, it was transformed to forsterite (Mg2 SiO4) at 820°C by rearrangement of Mg, Si and O (Dehydroxylation 2). In addition, crystal structure of for-sterite had begun to transform at 800 °C , and gradually grown 3-dimensionally to enstatite (MgSiO3) by recrystalli-zation after the heating above 1,100 °C . And then finally transformed to spherical minerals. This study showed chrysotile structure was collapsed about 600-700°C by dehydroxylation. And then the fibrous chrysotile was trans-formed to forsterite and enstatite, as non-hazardous minerals. Therefore, this study indicates heat treatment can be used to detoxification of chrysotile.