TY - JOUR
T1 - Thermodynamic modeling of alkali-activated fly ash paste
AU - Chen, Yun
AU - Ma, Bin
AU - Chen, Jiayi
AU - Li, Zhenming
AU - Liang, Xuhui
AU - de Lima, Luiz Miranda
AU - Liu, Chen
AU - Yin, Suhong
AU - Yu, Qijun
AU - Lothenbach, Barbara
AU - Ye, Guang
PY - 2024
Y1 - 2024
N2 - Previously, the lack of a thermodynamic database for N-(C-)A-S-H gel limited the application of thermodynamic modeling to alkali-activated fly ash (AAFA). This study pioneers thermodynamic modeling of AAFA using a recently developed thermodynamic dataset for N-(C-)A-S-H gel. The reaction products, pore solutions and reaction kinetics of AAFA pastes were experimentally determined. Based on the reaction kinetics, the composition of the solid phases and the pore solution of AAFA were modeled over time. The results showed that the simulated compositions of the solid reaction products and pore solution match closely with the experimental results, especially for the sodium hydroxide-activated system. Moreover, modeling results point out the potential presence of minor reaction products (e.g., C-(N-)A-S-H gel, microcrystalline ferrihydrite, Mg-containing phases) undetectable by experimental techniques. The study also demonstrated that thermodynamic modeling accurately captured the amount of bound water in reaction products, highlighting its robustness in both qualitative and quantitative analysis.
AB - Previously, the lack of a thermodynamic database for N-(C-)A-S-H gel limited the application of thermodynamic modeling to alkali-activated fly ash (AAFA). This study pioneers thermodynamic modeling of AAFA using a recently developed thermodynamic dataset for N-(C-)A-S-H gel. The reaction products, pore solutions and reaction kinetics of AAFA pastes were experimentally determined. Based on the reaction kinetics, the composition of the solid phases and the pore solution of AAFA were modeled over time. The results showed that the simulated compositions of the solid reaction products and pore solution match closely with the experimental results, especially for the sodium hydroxide-activated system. Moreover, modeling results point out the potential presence of minor reaction products (e.g., C-(N-)A-S-H gel, microcrystalline ferrihydrite, Mg-containing phases) undetectable by experimental techniques. The study also demonstrated that thermodynamic modeling accurately captured the amount of bound water in reaction products, highlighting its robustness in both qualitative and quantitative analysis.
KW - Alkali-activated fly ash
KW - Image analysis
KW - Pore solution
KW - Reaction kinetics
KW - Thermodynamic modeling
UR - http://www.scopus.com/inward/record.url?scp=85206922434&partnerID=8YFLogxK
U2 - 10.1016/j.cemconres.2024.107699
DO - 10.1016/j.cemconres.2024.107699
M3 - Article
AN - SCOPUS:85206922434
SN - 0008-8846
VL - 186
JO - Cement and Concrete Research
JF - Cement and Concrete Research
M1 - 107699
ER -