Effect of Blast-Furnace Slag Replacement Ratio and Curing Method on Pore Structure Change after Carbonation on Cement Paste

Kim, Junho; Na, Seunghyun; Hama, Yukio

doi:10.3390/ma13214787

Cited by 9 publications

(4 citation statements)

References 31 publications

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“…Like the trends reported in [ 32 , 33 , 34 ], the porosity results showed that S g series and F g series showed less porosity than C g series. In addition, CCHG also brought about a minimal filler effect, as confirmed by Figure 9 .…”

Section: Resultssupporting

confidence: 80%

“…Of course, those existing studies treated the materials to meet the aim of their studies. However, the usual cases use the FA or BFS as a supplementary material to the cement, therefore, the packing effect of FA and BFS [ 32 , 33 , 34 ] had a negative effect on the CO 2 sequestration in this study. The packing effect was confirmed by the MIP results, which showed that the porosity was significantly reduced than C-G0 and C-G5 before CO 2 -ppm.…”

Section: Resultsmentioning

confidence: 73%

“…It was considered that the filler effect from BFS and FA disturbed the improvement in CO 2 sequestration performance. As is well known, BFS and FA make cement composites denser [ 32 , 33 ]. This means that the porosity is reduced, in other words, the path of airflow is also reduced.…”

Section: Resultsmentioning

confidence: 99%

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Performance Assessment of Carbon Dioxide Sequestration in Cement Composites with a Granulation Technique

Lee,

Kim,

Min

et al. 2023

Materials

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The cement industry emits a significant amount of carbon dioxide (CO2). Therefore, the cement industry should recycle the emitted CO2. However, sequestration by carbonation in cement composites absorbs a very small amount of CO2. Therefore, a direct way of achieving this is to improve the absorption performance of CO2 in cement composites. In this study, to improve absorption, unlike in existing studies, a granulation technique was applied, and the material used was calcium hydroxide (CH). In addition, granulated CH was coated to prevent a reaction during the curing of cement paste. The coated CH granule (CCHG) was applied to 5% of the cement weight as an additive material, and the specimens were cured for 91 days to wait for the coating of CCHG to fully phase-change. The experiment of CO2 absorption showed an unexpected result, where the use of blast furnace slag (BFS) and fly ash (FA) had a negative effect on CO2 sequestration. This was because BFS and FA had a filler effect in the cement matrix, and the filler effect caused the blocking of the path of CO2. In addition, BFS and FA are well-known pozzolanic materials; the pozzolan reaction caused a reduction in the amount of CH because the pozzolan reaction consumed the CH to produce a calcium silicate hydrate. Therefore, the pozzolan reaction also had a negative effect on the CO2 sequestration performance combined with the filler effect. The CO2 sequestration efficiency was decreased between ordinary cement paste and BFS-applied specimens by 45.45%. In addition, compared to cases of ordinary cement paste and FA-applied specimens, the CO2 sequestration performance was decreased by 63.64%. Comprehensively, CO2 sequestration performance depends on the porosity and amount of CH.

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Section: Resultssupporting

confidence: 80%

Section: Resultsmentioning

confidence: 73%

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Performance Assessment of Carbon Dioxide Sequestration in Cement Composites with a Granulation Technique

Lee,

Kim,

Min

et al. 2023

Materials

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“…For decades, studies into supplementary cementitious materials (SCMs) have demonstrated their viability as partial replacements of PC, and for providing technological and environmental benefits [ 2 ]. The most widely used SCMs are fly ash (FA) [ 3 , 4 , 5 ], silica fume (SF) [ 6 , 7 ], or blast furnace slag (BFS) [ 8 , 9 ]. Fluid catalytic cracking catalyst residue (FCC) use has been studied since the late 1990s by various research groups worldwide [ 10 , 11 , 12 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

Influence of Accelerators on Cement Mortars Using Fluid Catalytic Cracking Catalyst Residue (FCC): Enhanced Mechanical Properties at Early Curing Ages

Soriano,

Borrachero,

Giménez-Carbo

et al. 2024

Materials

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Supplementary cementitious materials (SCMs) have been used in the construction industry to mainly reduce the greenhouse gas emissions associated with Portland cement. Of SCMs, the petrochemical industry waste known as fluid catalytic cracking catalyst residue (FCC) is recognized for its high reactivity. Nevertheless, the binders produced using SCMs usually present low mechanical strength at early curing ages. This study aims to assess the effect of different accelerating additives (KOH, sodium silicate SIL, commercial additive SKR) on the mechanical strength of mortars containing FCC. The results show that after only 8 curing hours, the compressive strength gain of the FCC mortars containing SKR was over 100% compared to the FCC mortar with no additive (26.0 vs. 12.8 MPa). Comparing the compressive strength of FCC mortar containing SKR to the control mortar, the enhancement is spetacular (6.85 vs. 26.03 MPa). The effectiveness of the tested accelerators at 8–24 curing hours was KOH ≈ SIL < SKR, whereas it was KOH < SIL < SKR for 48 h–28 days. The thermogravimetric data confirmed the good compatibility of FCC and the commercial accelerator.

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Comparing the Carbonation Performances of a Low-Clinker Blended Slag Cement with an Alkali-Activated Slag via Thermodynamic Modelling

2023

International RILEM Conference on Synergising Expertise Towards Sustainability and Robustness of Cement-Based Materials and Con

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Effect of Blast-Furnace Slag Replacement Ratio and Curing Method on Pore Structure Change after Carbonation on Cement Paste

Cited by 9 publications

References 31 publications

Performance Assessment of Carbon Dioxide Sequestration in Cement Composites with a Granulation Technique

Performance Assessment of Carbon Dioxide Sequestration in Cement Composites with a Granulation Technique

Influence of Accelerators on Cement Mortars Using Fluid Catalytic Cracking Catalyst Residue (FCC): Enhanced Mechanical Properties at Early Curing Ages

Comparing the Carbonation Performances of a Low-Clinker Blended Slag Cement with an Alkali-Activated Slag via Thermodynamic Modelling

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