Carbonization firing, charcoal firing, and carburizing are firing methods used for the purpose of coating the pottery with soot. Countries such as Korea, China, and Japan, where these techniques were developed, have various methods of trapping carbon in the clay. Carbonization firing, which was used as a method of producing soft and hard pottery before celadon was produced, was carried out for the purpose of producing architectural and household ornaments with the purpose of strength and waterproofing. This study categorizes the carbonization firing method based on 1000℃ and aims to elucidate the characteristics of the high-temperature carbonization firing method at a temperature higher than that. Roof tiles, bricks, and earthenware are fired at temperatures between 900℃ and 1100℃, while hard pottery fired at a temperature higher than that, puredogi, is fired at 1150~1210℃, the temperature at which salt vaporizes and melts. Carbonized hard pottery with strength at a temperature high enough to melt ash has been produced since the Three Kingdoms period and has been actively manufactured and used until modern times. In modern times, it is used for traditional pottery production, hard pottery, and ceramic art production. The purpose of this study is to clarify how high-temperature carbonization firing is performed and under what conditions it reacts. If the low-temperature carbonization firing method is the action of penetrating carbon into the pores of the clay body, high-temperature carbonization firing is characterized by solid solution and carburization, which are melting bonds between carbon and metal oxides such as iron. Therefore, clay without iron can be said to be an unsuitable material for high-temperature carbonization firing. Therefore, it was clarified that white porcelain clay with close to 0% iron does not carburize between the pores of the clay body during high-temperature carbonization firing, and the carbonized result by adding iron oxide to white porcelain clay was clarified and compared with carbonized pottery clay with the same iron oxide content. The specimens were made of porcelain clay, porcelain clay containing iron oxide, porcelain clay containing cobalt oxide, copper oxide, and chromium oxide, and glazed specimens, and the firing was performed in a wood-fired kiln for puree bowl firing, a gas kiln for carbonization, and a refractory brick experimental kiln for carbonization. As a result, the porcelain clay had no or minimal carbon reaction, and the higher the iron content, the greater the reaction with carbon. The reactions with other metal oxides, such as cobalt oxide, copper oxide, and chromium oxide, were minimal. It can be said that the high-fidelity carbonization firing is the result of solid solution and carburization due to the bonding phase of the molten metal oxide when the clay is sintered and the carbon bonding reaction with iron.