Relationships between Shear Strength Parameters with Mineralogy and Index Properties of Compacted, Unsaturated Soils

Each sample (BFS, WES, WIS, BES) yielded five compacted specimens with different water content and dry unit weights, ranging from the dry side, optimum water content, and wet side of compacting curves. Dividing the four soil samples into twenty compacted specimens supplied the soil suction test and consolidated undrained test. The laboratory estimated the consistent results by averaging two for each tested specimen.

The free swell ratio (FSR) is the ratio of the equilibrium sediment volume of 10 g oven-dried soil passing through a 425-μm sieve in distilled water versus kerosene, as described in Equation 9. V_d is the volume (ml) of soil specimen in water, and V_k (ml) is the volume (ml) of soil specimen in kerosene. Sridharan and Prakash [39] proposed the method for the free swell ratio test. Table 2 in Appendix 1 provides information on the swelling potential and soil mineralogy. (9) FSR=VdVK {\rm{FSR}} = {{{{\rm{V}}_{\rm{d}}}} \over {{{\rm{V}}_{\rm{K}}}}}

The soil suction measurement using a filter paper was conducted according to the standard [42]. A sharpened drive cylinder pushed into the compacted soil specimen, producing a cylindrical sub-specimen, 75 mm in diameter and 70 mm long for the soil suction test. Cutting the soil specimen in half allowed the best contact with the filter paper for matric suction measurement, with the top half in place, an electrical tape provided an outer seal around the filter paper–specimen interface, and the specimen was placed in a glass jar. A clean PVC O-ring with a sharp edge was inserted, facing up, on top of the soil specimen. The non-contact filter paper was placed over the PVC O-ring for total suction measurement. The glass jars were sealed using an airtight lid to prevent moisture exchange. The glass jars were labelled and placed in a temperature-controlled ice chest for an equilibrium time of 3 weeks. After the equilibrium time was completed, the filter papers were retrieved and weighed. The water contents W_f in non-contact and contact filter paper were calculated using Equation 10 for total and matric suction measurements, respectively. M_w is the mass of water in the filter paper, and M_f is the mass of the dry filter paper. The suction values were determined using the calibration curves in Figure 2. (10) Wf=MwMf×100 {{\rm{W}}_{\rm{f}}} = {{{{\rm{M}}_{\rm{w}}}} \over {{{\rm{M}}_{\rm{f}}}}} \times 100

Figure 2:

Whatman No. 42 filter paper calibration curve [4].

The triaxial test was conducted according to the standard [47]. The specimen measured 300 mm in height and 150 mm in diameter with a diameter/height ratio of 1.2. The soil specimens were prepared within the range of (11 – 12) kg. After oven drying, a sufficient mass of soil (plus 10 %) and water were mixed to produce a specimen. The water volumes were based on Proctor test results. Vibro-compaction required five equal layers, each with a duration of five minutes. An extruder removed the specimen from the mould, which was then trimmed to the required dimensions and weighed. Figure 3 shows the equipment for triaxial testing. The consolidated undrained (CU) triaxial test measured the shear strength characteristics of the prepared soil specimens. A set of three static triaxial tests provided data for each density/water content condition. The confining pressures for these three tests are 50, 100, and 150 kPa.

Figure 3:

Triaxial testing apparatus.

Figures 7 and 8 depict the relationship between (ϕ‘) and soil parameters: water content, Gs, LL and PI. Figure 7 illustrates the surface plot of (ϕ‘), water content and Gs. ϕ‘ decreases as Gs increases, displaying a strong correlation (R²=0.72) with Gs as given in Equation 11 in Table 10, Appendix 3. The correlation highlights the influence of Gs on ϕ‘, a result consistent with the findings published by [64]. The ϕ‘ of tested soils decreases as water content increases, following a strong correlation (R²=0.71) provided in Equation 12 in Table 10, Appendix 3. The increment in water content within the soil material reduces the resistance to interlocking of soil particles, aligning with other studies published by [14, 15, 65, 66, 67] emphasising on the strong dependency of water content on ϕ'. Figure 8 exhibits the surface plot of ϕ', LL and PI. ϕ' decreases with the increasing of LL, displaying a moderate exponential correlation (R²=0.68) described in Equation 13 in Table 10, Appendix 3. Similarly, ϕ' decreases as the PI of the soil sample increases, showing a moderate relationship (R²=0.64) described in Equation 14, Table 10, Appendix 3. The trend can be attributed to the reduction in resistance to the interlocking of soil particles with the increase of Atterberg limits due to water content. The results correspond with the findings reported by [19, 68, 69], indicating a moderate influence of Atterberg limits on the friction angle.

Figure 7:

3D relationship of (ϕ‘) dependence on W (%) and Gs.

Figure 8:

3D relationship of (ϕ‘) dependence on liquid limit and plasticity index.

Figures 31 to 33 in Appendix 8 compare the relationships between the friction angle (ϕ‘) and water content, specific gravity and liquid limit from this study with the results from other researchers such as [14, 15, 65, 67, 76, 68]. Similar trends are observed from the data graphs (Figures 31–33), the friction angle decreases as water content, specific gravity, and liquid limit increase. The marginal discrepancies observed stem from the soil material’s variability and the limited number of soil specimens utilised by other researchers.

Figures 9 and 10 present a three-dimensional representation of the relationship between ϕ', fine content, clay content, dry unit weight (γ_d) and void ratio. Figure 9 displays a three-dimensional graph of ϕ‘, fine content and clay content. ϕ' decreases as the fine content increases in soil material, portraying a strong correlation (R²=0.72) as provided in Equation 15 in Table 10, Appendix 3. The friction angle decreases with the increase in clay content within the soil, exhibiting a strong correlation (R²=0.74) described in Equation 16 in Table 10, Appendix 3. The reaction of fine-grained particles with water reduces the resistance to the interlocking of soil particles, aligning with studies reported by [70, 71]. Figure 10 portrays the surface plot of ϕ', dry unit weight and void ratio. The ϕ' angle increases with an increase in dry unit weight, showing a moderate correlation (R²=0.62) with dry unit weight as described in the exponential Equation 17 in Table 10, Appendix 3. The finding agrees with studies reported by [14, 72, 15] on the shear strength of expansive soils. ϕ‘ of soil material decreases as the void ratio increases, exhibiting a moderate correlation (R²=0.70) with the void ratio described in Equation 18 in Table 10, Appendix 3. The result aligns with research published by [24, 17] on the impact of soil fabric on shear strength.

Figure 9:

3D relationship of (ϕ‘) dependence on fine content (%) and clay content (%).

Figure 10:

3D relationship of (ϕ‘) dependence on dry unit weight and void ratio.

Figures 11 and 12 portray a three-dimensional description of the correlation between ϕ‘ and soil characteristics such as free swell ratio (FSR), free swell index (FSI), smectite content and plagioclase content. Figure 11 illustrates the relationship among ϕ', FSR and FSI. The friction angle decreases as FSR increases. The exponential Equation 19 in Table 10, Appendix 3, demonstrates a strong correlation (R²=0.74) between ϕ' and FSR. ϕ' decreases with an increase in FSI of the tested soil, as indicated by the strong correlation (R²=0.70) described in Equation 20 in Table 10, Appendix 3. ϕ' decreases with a higher swelling potential, aligning with the findings from reports by [16, 73] for similar soils. Figure 12 shows a surface plot of ϕ', smectite content and plagioclase content. As the smectite content increases, ϕ' decreases with a moderate correlation (R²=0.61) as described in Equation 21 in Table 10, Appendix 3. This indicates that clay mineral (smectite) content influences ϕ'. The results are in line with research published by [30, 31], demonstrating the decrease in ϕ' with the increment of clay mineral quantity. On the other hand, ϕ‘ increases with the increase in plagioclase content and portrays a moderate correlation (R²=0.53) described in Equation 22 in Table 10, Appendix 3. The trend can be attributed to the presence of plagioclase, enhancing the resistance to interlocking of soil particles. Figure 37 in Appendix 4 describes the correlation diagram of ϕ‘ and the soil properties.

Figure 11:

3D relationship of (ϕ‘) dependence on FSR and FSI (%).

Figure 12:

3D relationship of (ϕ‘) dependence on smectite (%) and plagioclase (%).

Figures 13 and 14 describe the correlation between the matric suction angle (ϕ^b) and the soil features such as fine content, clay content, LL and PI. Figure 13 presents a surface plot of ϕ^b, fine content and clay content. ϕ^b decreases as the fine content increases and exhibits a strong correlation (R²=0.92) given in Equation 23 in Table 11, Appendix 3. ϕ^b decreases with an increase in clay content and demonstrates a strong correlation (R²=0.92) described in Equation 24 in Table 11, Appendix 3. The trend corroborates other studies reported by [30, 31] for similar expansive soils. Figure 14 shows the correlation between ϕ^b, LL and PI. ϕ^b decreases as the LL and PI increase. ϕ^b demonstrates a strong correlations with R²=0.93 for LL and R²=0.92 for PI as given in Equations 25 and 26 in Appendix 3, respectively. The findings are in line with the results reported by [19, 15], highlighting the influence of Atterberg limits on the shear strength of unsaturated soils.

Figure 13:

3D relationship of (ϕ^b) dependence on fine content (%) and clay content (%).

Figure 14:

3D relationship of (ϕ^b) dependence on liquid limit (%) and plasticity index (%).

Figures 15 and 16 describe the relationship between ϕ^b and soil parameters: Gs, γ_d, water content, and air entry value. Figure 15 illustrates the surface plot of ϕ^b, Gs, and γ_d. ϕ^b decreases as Gs increases, showing a strong correlation (R²=0.88) with Gs, as described in Equation 27 in Table 11, Appendix 3. This trend can be justified by the increase in Gs with the augmentation of clay content, leading to an increment of negative pore pressure and a subsequent decrease in ϕ^b. ϕ^b increases with an increase in γ_d of the soil material, showing a strong correlation (R²=0.81) with γ_d as given in Equation 28 in Table 11, Appendix 3. These results are consistent with studies reported by [21, 14, 15] on the shear strength of unsaturated soils. Figure 16 describes a surface plot of ϕ^b, water content, and AEV. ϕ^b decreases as water content increases, exhibiting a strong correlation (R²=0.88) with water content as given in Equation 29 in Table 11, Appendix 3. The results align with research published by [14, 15, 16], showing a decrease in the shear strength of expansive soils with the increase of water content. ϕ^b decreases with an increase in AEV, showing a very strong correlation (R²=0.92) with AEV as described in Equation 30 in Table 11, Appendix 3. The trend is in line with the results published by [27, 28, 29], reporting the influence of AEV on unsaturated shear strength.

Figure 15:

3D relationship of (ϕ^b) dependence on Gs and dry unit weight.

Figure 16:

3D relationship of (ϕ^b) dependence on water content (%) and air entry value.

Figures 17 and 18 illustrate the three-dimensional relationship between ϕ^b and smectite content, FSI, plagioclase content and K-feldspar content. Figure 17 depicts the surface plot of ϕ^b, smectite content, and FSI. ϕ^b decreases as FSI increases, showing a very strong correlation (R²=0.93) with FSI as described in Equation 31 in Table 11, Appendix 3. The decrease in shear strength with the increment of swelling potential aligns with findings from reports by [74, 16, 73] on unsaturated shear strength. ϕ^b decreases with an increase in smectite content, showing a strong correlation (R²=0.79) with smectite content according to Equation 32 in Table 11, Appendix 3. The proportion of smectite significantly impacts the shear strength of expansive soils, and the results are consistent with studies reported by [20, 30, 31] on similar soils. Figure 18 presents a surface plot of ϕ^b, plagioclase content, and K-feldspar content. ϕ^b increases with higher plagioclase content in soil material, showing a moderate correlation (R²=0.67) with plagioclase content described in Equation 33 in Table 11, Appendix 3. ϕ^b increases with higher K-feldspar content, displaying a moderate correlation (R²=0.66) with K-feldspar as outlined in Equation 34 in Table 11, Appendix 3. Figure 38 in Appendix 5 describes the correlation diagram of ϕ^b and the soil properties.

Figure 17:

3D relationship of (ϕ^b) dependence on smectite (%) and FSI (%)

Figure 18:

3D relationship of (ϕ^b) dependence on plagioclase (%) and K-feldspar (%)

Figures 19 and 20 provide a three-dimensional description of the correlation between c‘ and soil features such as water content, Gs, LL and PI. Figure 19 presents a surface plot of c‘, water content, and Gs. c‘ decreases as water content increases and demonstrates a strong correlation (R²=0.73) as given in Equation 35 in Table 12, Appendix 4. This trend can be explained by the decrease in intermolecular bonds between the water and grain particles with the increase in water content. The observation is in line with the reports published by [13, 14, 75, 66, 17], presenting a strong dependency of c‘ on water content. c‘ decreases with an increase in Gs and exhibits a strong correlation (R²=0.71) as described in Equation 36 in Table 12, Appendix 4. The finding aligns with the study reported by [64] on variability in the geotechnical properties of clay soils. It appeared that Gs and water content influence soil cohesion. Figure 20 displays the surface plot of c‘, LL, and PI. The surface plot illustrates a reduction in c‘ with the increase in LL, and PI. The correlation between c‘, LL and PI demonstrates a moderate correlation with (R²=0.61) for LL and (R²=0.56) for PI as described in Equations 37 and 38, respectively, in Table 12, Appendix 4. The trend can be attributed to the fact that LL and PI increase with the increment of water and reduce the intermolecular bond between the adsorbed water surrounding each grain in soil material. The LL and PI influence the magnitude of soil cohesion. The findings align with the results reported by [69, 68, 76] depicting the influence of Atterberg limits on soil cohesion.

Figure 19:

3D relationship of (c‘) dependence on water content (%) and specific gravity.

Figure 20:

3D relationship of (c‘) dependence on liquid limit (%) and plasticity index (%).

Figures 34 to 36 in Appendix 8 compare the relationships between the effective cohesion (c‘) and water content, specific gravity and liquid limit from this study with the results from other scholars like [14, 15, 65, 67, 76, 68]. Similar trends are observed from the data graphs (Figures 34 to 36), the friction angle decreases as water content, specific gravity, and liquid limit increase. The marginal discrepancies observed stem from the soil material’s variability and the limited number of soil specimens utilised by other researchers.

Figures 21 and 22 describe the correlation between c‘ and soil features such as fine content, clay content, void ratio, and γ_d. Figure 21 presents the surface plot of c‘, fine content, and clay content. There is a tendency for c‘ to decrease when the fine content increases. c‘ shows a moderate correlation (R²=0.68) with fine content described in Equation 39 in Table 12, Appendix 4. Similarly, c‘ tends to decrease as the clay content in soil grows. c‘ portrays a strong correlation (R²=0.71) with clay content as given in Equation 40 in Table 12, Appendix 4. The trend can be explained by the fact that clays and silts react with water, change sizes and reduce the intermolecular bond between the adsorbed water surrounding each grain. The findings agree with the trends observed in the studies published by [20, 30] on the shear strength of swelling soils. Figure 22 shows the surface graph of c‘, void ratio and γ_d. c‘ decreases as the void ratio increases, indicating a moderate correlation (R²=0.64) described in Equation 41 in Table 12, Appendix 4. The trend stems from the presence of significant amounts of clays and silts that lead to more voids and less particle-to-particle contact. Consequently, the increase in the void ratio reduces soil cohesion. The observation agrees with other research studies reported by [24, 71, 17, 76] on the shear strength properties of soil materials. c‘ increases when γ_d increases and exhibits a moderate correlation (R²=0.54) described in Equation 42 in Table 12, Appendix 4. The increment of γ^d enhances the intermolecular bond between the adsorbed water surrounding each grain in the soil material justified the trend. The finding concurs with the studies published by [14, 15, 76] on similar soils. The void ratio and dry unit weight influence the soil cohesion.

Figure 21:

3D relationship of (c‘) dependence on fine content (%) and clay content (%).

Figure 22:

3D relationship of (c‘) dependence on dry unit weight and void ratio.

Figures 23 and 24 describe the relationship between c‘ and soil parameters: smectite content, FSI, K-feldspar content, and plagioclase content. Figure 23 portrays the surface plot of c‘, smectite content and FSI. c‘ decreases with the growth of smectite content and exhibits a moderate correlation (R²= 0.52) with the smectite content described in Equation 43 in Table 12, Appendix 4. The results align with the studies published by [20, 31], indicating that c‘ decreases with the increment of clay minerals within the soil. Another study reported by [30] stated that c‘ reduces when the quantity of clay minerals increases. Similarly, c‘ decreases when the FSI of soil increases and displays a moderate correlation (R²=0.62) described in Equation 44 in Table 12, Appendix 4. The trend is consistent with other investigations reported by [16, 73] for similar expansive soils. Figure 24 shows the surface graph of c‘, K-feldspar content, and plagioclase content. c‘ increases when K-feldspar content increases and shows a moderate correlation (R²=0.53) with K-feldspar content, as given in Equation 45 in Table 12, Appendix 4. c‘ increases when the plagioclase content grows and portrays a moderate correlation (R²=0.51) with plagioclase content described in Equation 46 in Table 12, Appendix 4. Figure 39 in Appendix 5 describes the correlation diagram of c‘ and the soil properties.

Figure 23:

3D relationship of (c‘) dependence on smectite (%) and free swell index (%).

Figure 24:

3D relationship of (c‘) dependence on K-feldspar (%) and plagioclase (%).