Conductance of tricalcium silicate in water

In tricalcium silicate at 15OO°C up to 1.4 % K20 , 1.4 % Na20 and 1.2 % Li20, respectively, can be incorporated. The following structural substitution types were found: K replaces Ca with valency balance by removal of oxygen; Na replaces Ca and occupies interstitial sites, in addition some oxygen at

The mutual interaction of tricalcium silicate (CRS) and B-dicalcium silicate (B-CpS) in their combined h~dration was studied. The rate of B-CpS hydration was accelerated significantly in the presenc~ of CRS. The rate of CRS hydration was retarded, but only i~ the presence of~large amounts of B-C2S.

Based on conceptual models for the stages in the hydration of trlcalcium silicate, a mathematical model was developed. The separate resistances in the mathematical model correspond to the phenomenological stages of the conceptual model. Comparison of model output with available hydration data gave a

Calcium monosilicoaluminate C3A.CaSi03o12 H20 and calcium trisilicoaluminate C3A.3 CaSi03o3] H20 have been identzfied in pastes of C3S + C3A. Electron probe microanalysis and scanning electron microscopy with energy X-ray dispersive analysis show that silieoaluminates are both formed around C3A grai

The relative tendency of different Portland cements to remove chloride ions from concrete mix water by forming insoluble complexes is an important determinant of the corrosion behaviour of steel in concrete. Whilst the C3A phase plays a dominant role in binding chloride ions, other cement minerals m