炼钢
自行车
碳纤维
环境科学
冶金
计算机科学
材料科学
地理
考古
算法
复合数
作者
Yihong Yu,Ziyu Mei,Qi Zhang,Chuangwei Liu,Yan Sun,Hao Zhang,Gaowu Qin,Song Li
摘要
ABSTRACT The conventional steelmaking process emits 1.8 tons of CO 2 to produce 1 ton of crude steel, making the steel industry the world's largest emitting manufacturing sector. Here, we propose and demonstrate a renewable route based on electrified carbon cycling, which significantly reduces CO 2 emission by 83%. The critical step of the route involves electrochemical CO 2 reduction (CO 2 RR) to produce CO‐rich syngas, which reduces iron ore into metallic iron (Fe x O y ‐to‐Fe), effectively closing the carbon cycling. A technoeconomic analysis (TEA) reveals that the energy efficiency of this novel process is dependent on the operating parameters of CO 2 RR, with optimal efficiency occurring at the current density range of 150‐200 mA cm −2 . As a proof‐of‐concept study, sulfur vacancy (V S )‐engineered Ag 3 CuS 2 was developed as a high‐performance CO 2 RR electrocatalyst. This catalyst yields a CO‐rich syngas at a high Faradaic efficiency ( FE ) close to 100% at a cell voltage of 2.5 V. The CO 2 RR‐produced syngas effectively reduced iron oxide into metallic iron. The implementation of electrified carbon cycling significantly increases the utilization of electricity in steel production, reaching 88.7%. This research describes a sustainable way to reshape the ironmaking process and ultimately neutralize the steel industry.
科研通智能强力驱动
Strongly Powered by AbleSci AI