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Chemical and physical effects of high-volume limestone powder on sodium silicate-activated slag cement (AASC)
https://orcid.org/0000-0003-3030-1317
https://orcid.org/0000-0002-1149-4865
Highlights Proper use of LS can increase fluidity and prolong setting time without losing strength. LS can affect reaction products of AAS and its function depends on mix proportions. Variations of pore structure of modified AAS cement relies on the dosage of LS. Around 30% hydration degree of LS was achieved at 28 d for AAS with 40% LS.
Abstract This study aims at discussing physical and chemical influence of limestone powder (LS) on the AAS system. General properties, including fluidity, setting time, drying shrinkage, and mechanical strength of AAS pastes/mortars, were examined. Pore structure change and phase assemblages of LS-AAS composites were studied. The results showed that the addition of 50 wt% LS increased the fluidity and setting time of AAS pastes, but reduced the total drying shrinkage of AAS mortars. Meanwhile, around 30% reduction in mechanical properties were found at the same replacement ratio. The pore structure was refined in the pastes with LS replacement<25 wt%, but was coarsened in the sample with 40 wt% LS. Limited new phase was formed in the sodium silicate activated slag samples, which was believed to depend on the modulus of the activator. Around 30% hydration degree of LS was achieved in 40 wt% LS-replaced AAS pastes hydrated for 7 ~ 28 d as determined by TG-DSC analysis. The main drawbacks of AAS, fluidity, setting time, and drying shrinkage, are improved by using high-volume LS, so use of high-volume LS in AAS system can be an option for the purpose of environmental protection.
Chemical and physical effects of high-volume limestone powder on sodium silicate-activated slag cement (AASC)
https://orcid.org/0000-0003-3030-1317
https://orcid.org/0000-0002-1149-4865
Highlights Proper use of LS can increase fluidity and prolong setting time without losing strength. LS can affect reaction products of AAS and its function depends on mix proportions. Variations of pore structure of modified AAS cement relies on the dosage of LS. Around 30% hydration degree of LS was achieved at 28 d for AAS with 40% LS.
Abstract This study aims at discussing physical and chemical influence of limestone powder (LS) on the AAS system. General properties, including fluidity, setting time, drying shrinkage, and mechanical strength of AAS pastes/mortars, were examined. Pore structure change and phase assemblages of LS-AAS composites were studied. The results showed that the addition of 50 wt% LS increased the fluidity and setting time of AAS pastes, but reduced the total drying shrinkage of AAS mortars. Meanwhile, around 30% reduction in mechanical properties were found at the same replacement ratio. The pore structure was refined in the pastes with LS replacement<25 wt%, but was coarsened in the sample with 40 wt% LS. Limited new phase was formed in the sodium silicate activated slag samples, which was believed to depend on the modulus of the activator. Around 30% hydration degree of LS was achieved in 40 wt% LS-replaced AAS pastes hydrated for 7 ~ 28 d as determined by TG-DSC analysis. The main drawbacks of AAS, fluidity, setting time, and drying shrinkage, are improved by using high-volume LS, so use of high-volume LS in AAS system can be an option for the purpose of environmental protection.
Chemical and physical effects of high-volume limestone powder on sodium silicate-activated slag cement (AASC)
https://orcid.org/0000-0003-3030-1317
https://orcid.org/0000-0002-1149-4865
Highlights Proper use of LS can increase fluidity and prolong setting time without losing strength. LS can affect reaction products of AAS and its function depends on mix proportions. Variations of pore structure of modified AAS cement relies on the dosage of LS. Around 30% hydration degree of LS was achieved at 28 d for AAS with 40% LS.
Abstract This study aims at discussing physical and chemical influence of limestone powder (LS) on the AAS system. General properties, including fluidity, setting time, drying shrinkage, and mechanical strength of AAS pastes/mortars, were examined. Pore structure change and phase assemblages of LS-AAS composites were studied. The results showed that the addition of 50 wt% LS increased the fluidity and setting time of AAS pastes, but reduced the total drying shrinkage of AAS mortars. Meanwhile, around 30% reduction in mechanical properties were found at the same replacement ratio. The pore structure was refined in the pastes with LS replacement<25 wt%, but was coarsened in the sample with 40 wt% LS. Limited new phase was formed in the sodium silicate activated slag samples, which was believed to depend on the modulus of the activator. Around 30% hydration degree of LS was achieved in 40 wt% LS-replaced AAS pastes hydrated for 7 ~ 28 d as determined by TG-DSC analysis. The main drawbacks of AAS, fluidity, setting time, and drying shrinkage, are improved by using high-volume LS, so use of high-volume LS in AAS system can be an option for the purpose of environmental protection.
Chemical and physical effects of high-volume limestone powder on sodium silicate-activated slag cement (AASC)
Zhu, Xiaohong (author) / Kang, Xiaojuan (author) / Deng, Jiaxin (author) / Yang, Kai (author) / Jiang, Shouheng (author) / Yang, Changhui (author)
2021-04-04
Article (Journal)
Electronic Resource
English
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