TY - JOUR
T1 - Solubility of C-A-S-H phases with high degree of heavy metal ion substitution
AU - Baldermann, Andre
AU - Preissegger, Veronika
AU - Dietzel, Martin
N1 - Publisher Copyright:
© 2022 The Authors
PY - 2022/4/11
Y1 - 2022/4/11
N2 - Knowledge about interactions between cementitious materials and dissolved metal (Me) ions is key for environmental remediation and waste management, but thermodynamic data on this topic are still limited. We present solubility data for nanocrystalline C-A-S-H phases substituted by distinct Me ions with (Ca + Me)/(Si + Al) molar ratios from 0.86 to 1.04 and Ca2+ substitution of ∼ 48 mol% for Zn2+, ∼29 mol% for Co2+ and ∼ 27 mol% for Cu2+ in tobermorite-type Me-C-A-S-H. The solubility constants of the Me-C-A-S-H phases are significantly lower compared to pure C-A-S-H (logK = -8.3), ranging from logK = -8.6 to −11.3 for Co-C-A-S-H, logK = -9.1 to −11.6 for Cu-C-A-S-H and logK = -8.9 to −14.1 for Zn-C-A-S-H, as the Me content increases according to the expression: logKMe-C-A-S-H=0.11±0.03·%Mesubstitution-8.33±0.12;R2=0.89 independent on the type of incorporated Me ion. Thus, newly-forming C-A-S-H phases have a high immobilization potential for aqueous Me ions. The novel solubility data open the door for thermodynamic modelling of Me ion mobility in aquatic media.
AB - Knowledge about interactions between cementitious materials and dissolved metal (Me) ions is key for environmental remediation and waste management, but thermodynamic data on this topic are still limited. We present solubility data for nanocrystalline C-A-S-H phases substituted by distinct Me ions with (Ca + Me)/(Si + Al) molar ratios from 0.86 to 1.04 and Ca2+ substitution of ∼ 48 mol% for Zn2+, ∼29 mol% for Co2+ and ∼ 27 mol% for Cu2+ in tobermorite-type Me-C-A-S-H. The solubility constants of the Me-C-A-S-H phases are significantly lower compared to pure C-A-S-H (logK = -8.3), ranging from logK = -8.6 to −11.3 for Co-C-A-S-H, logK = -9.1 to −11.6 for Cu-C-A-S-H and logK = -8.9 to −14.1 for Zn-C-A-S-H, as the Me content increases according to the expression: logKMe-C-A-S-H=0.11±0.03·%Mesubstitution-8.33±0.12;R2=0.89 independent on the type of incorporated Me ion. Thus, newly-forming C-A-S-H phases have a high immobilization potential for aqueous Me ions. The novel solubility data open the door for thermodynamic modelling of Me ion mobility in aquatic media.
KW - C-A-S-H phase
KW - Environment
KW - Heavy metals, Solubility
KW - Water management
UR - http://www.scopus.com/inward/record.url?scp=85125920793&partnerID=8YFLogxK
U2 - 10.1016/j.conbuildmat.2022.126926
DO - 10.1016/j.conbuildmat.2022.126926
M3 - Article
AN - SCOPUS:85125920793
SN - 0950-0618
VL - 327
JO - Construction and Building Materials
JF - Construction and Building Materials
M1 - 126926
ER -