Effect of Compaction Degree on the Carbonation Properties of Steel Slag
Zihan Yan, Wenxiao Fu, Longbin Zhao, Ziyan Gao, Sitong Chen, Qianruo Wang, Wei Long

TL;DR
This paper shows how compacting steel slag affects its carbonation process, with optimal compaction improving strength and CO2 uptake.
Contribution
The study identifies an optimal compaction degree of 60% for maximizing carbonation performance in steel slag.
Findings
At 60% compaction, steel slag achieves a compressive strength of 124.4 MPa and CO2 uptake of 14.5%.
Higher compaction degrees block gas pathways, reducing carbonation efficiency.
Moderate compaction improves carbonation product bonding and performance.
Abstract
Carbonation technology offers a novel approach to enhance steel slag performance, where the compaction degree plays a pivotal role in optimizing the carbonation process. This study reveals that as the compaction degree increases, the peak temperature in the carbonation environment gradually decreases, and the intensity of the carbonation reaction weakens. Post-carbonating, the compressive strength initially increases before declining, peaking at a compaction degree of 60%. At this optimal compaction degree, the material achieves a compressive strength of 124.4 MPa and a CO2 uptake of 14.5%. The analysis of pore size distribution and carbonation products reveals that steel slag compacts with lower compaction degrees exhibit larger internal pores, leading to dispersed and isolated carbonation products, which restrict performance improvement. Conversely, excessively high compaction degrees…
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Taxonomy
TopicsConcrete and Cement Materials Research · Rock Mechanics and Modeling · Drilling and Well Engineering
