Experimental study on material ratio and strength performance of geopolymer-improved soil

•The ideal mixing ratio of metakaolin-based geopolymer binder was studied.•The cost-optimal mixing ratio of the geopolymer binder in clay soil was investigated.•The strength performance improvement of the geopolymer-improved soil was analyzed.•The stabilization effect of the geopolymer binder on cla...

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Bibliographic Details
Published in:Construction & building materials 2021-01, Vol.267, p.120469, Article 120469
Main Authors: Wang, Shengnian, Xue, Qinpei, Zhu, Yin, Li, Guoyu, Wu, Zhijian, Zhao, Kai
Format: Article
Language:English
Subjects:
Energy dispersive spectrometer (EDS)
Geopolymer binders
Geopolymer-improved soil
Optimal material ratio
Scanning electron microscope (SEM)
Strength performance
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Summary:•The ideal mixing ratio of metakaolin-based geopolymer binder was studied.•The cost-optimal mixing ratio of the geopolymer binder in clay soil was investigated.•The strength performance improvement of the geopolymer-improved soil was analyzed.•The stabilization effect of the geopolymer binder on clay soil was discussed. Geopolymer binder is a kind of green cementitious material with fast hardening, high strength, low shrinkage, and acid-alkali corrosion resistance. It is very beneficial to ensure the firmness, stability, and durability of subgrade structure in cold regions. In this study, the unconfined compression strength test of the clay soil improved by metakaolin-based geopolymer binder was carried out. The material ratio of the metakaolin-based geopolymer binder was analyzed, the optimal mixing ratio of the metakaolin-based geopolymer binder in the clay soil was investigated, and the impacts of metakaolin and alkali-activator on the mechanical properties of the geopolymer-improved soil were discussed. Experimental results indicate that the unconfined compression strength of the geopolymer-improved soil increases first and then decreases with the contents of metakaolin and alkali-activator (a mixture of unslaked lime (CaO) and sodium bicarbonate (NaHCO3) with the mass ratio of 1:1). The ideal mixing ratio of metakaolin and alkali-activator in the geopolymer binder is about 2:1, and the cost-optimal mixing ratio of the geopolymer binder in the clay soil is about 12%. By comparing with pure clay soil, lime soil, and ordinary Portland cement soil, the strength performance and stabilization effect of the geopolymer-improved soil were further studied through unconfined compression strength test, direct shear test, and Brazilian split-cylinder test. Outcomes show that the unconfined compression strength, shear strength, and Brazilian splitting strength of the geopolymer-improved soil have good advantages over the other three kinds of soils. The microstructure analysis by SEM with EDS illustrates that the agglomeration and stabilization effects of the geopolymer-improved soil, ordinary Portland cement soil, lime soil, and pure clay soil are weakened in turn, and the polymerization of the geopolymer binders can be in progress in the alkali-activated environment formed from the hydration of CaO and its reaction with NaHCO3. The failure of the geopolymer-improved soil with the increasing contents of metakaolin and alkali-activator shows that there is a tendency
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2020.120469