The intensity of C-S-H phase increa

The intensity of C-S-H phase increases in the cement replaced with BA comparing to without BA. From the results of Fig. 10, the intensity peaks of CSH for CBA10 and CBA20 in the XRD patterns of the CBA-admixed soft clay were almost similar to that of CBA0 but the intensity peaks of CBA20 is higher than CBA0.
X-ray diffraction (XRD) analysis of samples (CBA0, CBA10, CBA20 and CBA50) shows peaks of quartz (Q), calcium silicate hydrate (CSH), kaolinite (K), illite (I), Montmorillonite (M), calcium hydroxide (CH) and ettringite (E) phases on comparing the values of 2/d/I/I of the peaks by JCPDS data file (see Figs. 10). Peaks of different phases in treatments shows the intensity corresponding to the strength of simples. Tricalcium Silicate (C3S) is the major mineral component (>50%) found in cement and upon hydration forms calcium silicate hydrate or calcium silicate which hardens the cement slurry and is responsible for initial (1–3 days) and final strengths [47].
The second major component found in cement is dicalcium silicate (C2S). Larnite reacts with water to form calcium silicate hydrate or calcium silicate and portlandite, and responsible for the development of late strength. Neville [48], Molnar et al. [49] and Jumate and Manea [47] studied that hydration and hydrolysis reaction of C3S and C2S mineral components produce calcium silicate hydrate (also known as Tobermorite) gels and later the solid phase develops crystals during curing period leading to strengthening of the cement-concrete mixes.
In 20% CBA treated soft clay (see Fig. 10) the increased formation of CSH resulted in increased strength compared to 20% CBA control soft clay (see Fig. 10). Ettringite formation in 20% CBA treated soft clay, was nonexpansive and filled the pore structure in samples resulted in dense structure and increased the compressive strength. Min and Mingshu [50]. The XRD results (see Figs. 10) shows increased intensity of CSH and nonexpansive ettringite in CBA treated soft clay (10% and 20%) responsible for the strength development in concrete where as in 50% CBA treated soft clay, reduction in cement content reduced (needed for hydration reaction) which in turn decreased the CSH and thus reduced the strength compared to control sample.
Typical XRD patterns of the stabilized soils for CBA0 and CBA20 at 28 days curing time from Figure 10, showed growths of major reaction products which could be identified as CSH and ettringite. As obviously seen in Figures 11 and 13, X-ray intensities of CSH products and ettringite for CBA0 and CBA20 illustrated their formations similar to strength characteristic curves. In addition, the developed strength exhibited general trend to increase proportionally with amounts of CSH and ettringite. This can be observed as shown in Figure 12 and Figure 14. In essence, the higher reflections were obtained from the mixtures having relatively higher strength. It could therefore be concluded that these reaction products mainly contribute to strength development of the stabilized soils.