An alumina phase induced composite transition shuttle to stabilize carbon capture cycles.

Limiting global warming to 1.5-2 °C requires a 50-90% reduction in CO emissions in 2050, depending on different scenarios, and carbon capture, utilization, and storage is a promising technology that can help reach this objective. Calcium oxide (CaO) carbon capture is an appealing choice because of its affordability, large potential capacity, and ability to withstand the high temperatures of flue gases.

Integrated Utilization of Sewage Sludge and Coal Gangue for Cement Clinker Products: Promoting Tricalcium Silicate Formation and Trace Elements Immobilization.

The present study firstly proposed a method of integrated utilization of sewage sludge (SS) and coal gangue (CG), two waste products, for cement clinker products with the aim of heat recovery and environment protection. The results demonstrated that the incremental amounts of SS and CG addition was favorable for the formation of tricalcium silicate (C₃S) during the calcinations, but excess amount of SS addition could cause the impediment effect on C₃S formation. Furthermore, it was also observed that the C₃S polymorphs showed the transition from rhombohedral to monoclinic structure as SS addition was increased to 15 wt %.

A Fe-C-Ca big cycle in modern carbon-intensive industries: toward emission reduction and resource utilization.

Herein a big Fe-C-Ca cycle, clarifying the basic element flows and energy flows in modern carbon-intensive industries including the metallurgical industry and the cement industry, was proposed for the first time in the contexts of emission reduction and iron ore degradation nowadays. This big cycle was focused on three industrial elements of Fe, C and Ca and thus it mainly comprised three interdependent loops, i.e.