Steel slag is used for iron correction materials for cement production. Steel slag does not contain carbonate. It can not only replace iron ore when preparing cement clinkers, but also provides calcium, silicon and aluminum, which has a good carbon reduction effect.The main raw materials of the cement are calcium, silica, aluminum and iron materials. Each raw material forms the mineral phase of cement clinker through high temperature solid phase reaction. It can be seen from the chemical components, mineral characteristics, and micro -structures of the steel slag that the steel slag also contains RO, Feo, Fe2O3 and other iron phases, thereby having the conditions to replace iron correction materials. In addition, the steel slag also contains calcium, silicon, aluminum, etc. that can be burned into raw materials such as CAO (most of the content between 40% and 50%)), which can save some calcium, silicon and aluminum raw materials. In view of this steel slag fot iron correctional material technology route. Generally, tthe mineral component of iron correction material for cement is hematite Fe2O3, while the iron phase in steel slag mainly exists in the form of RO, FeO, Fe2O3, Fe, CF and so on. When steel slag is used as raw material, regardless of the form of iron, the iron phase in its high temperature solid phase reaction can provide the iron component to form the C4AF mineral phase required for cement clinker.Combined with the actual production, the target value of WISCO steel slag clinker for transportation to a cement company along the Yangtze River for burning cement clinker is KH=0.91士0.02, SM=2.5士0.1, IM=1.5士0.1. The LCA data set user must consider this data specifically for the carbon footprint associated with the production of cement clinker using steel slag as an iron correction material. It is crucial to note that the carbon emission values provided are cumulative of all the unit processes except the 'clinker calcination process'. Thus, when modeling the environmental impact of cement production, users should factor in additional emissions from the calcination stage to obtain a complete assessment of the carbon footprint. The life cycle boundary for this data is from cradle to gate, which does not include the downstream use phase or end of life stage. Users should apply the functional unit of 1t P·I type Portland cement accordingly.