Behavior of Lime-Stabilized Red Bed Soil after Cyclic Wetting-Drying in Triaxial Tests and SEM Analysis

Song, Zhengmin; Zhang, Dewen; Mao, Yuncheng; Mu, Yanhu; Zhang, Kun; Zhang, Qinglong

doi:https://doi.org/10.1155/2020/4230519

Advances in Materials Science and Engineering

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Abstract Introduction Results and Analysis Conclusions Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 4230519 | https://doi.org/10.1155/2020/4230519

Behavior of Lime-Stabilized Red Bed Soil after Cyclic Wetting-Drying in Triaxial Tests and SEM Analysis

Zhengmin Song,^1,2Dewen Zhang,³Yuncheng Mao,²Yanhu Mu,²Kun Zhang,⁴and Qinglong Zhang⁴

Academic Editor: Carlos R. Rambo

Received06 Nov 2019

Revised08 Feb 2020

Accepted06 Mar 2020

Published08 Apr 2020

Abstract

Most red beds demonstrate inferior geotechnical properties in natural conditions and need to be improved when used as construction material. In this study, a serious of triaxial tests, permeability tests, and scanning electron microscopy (SEM) analysis were carried out on lime-stabilized and untreated red bed soil after experiencing different wetting-drying (W-D) cycles. The test results showed that, with the increase in the added lime, the shear strength, strength parameters (including the cohesion and the internal friction angle), and the shear modulus of red bed soil increased gradually. For the untreated specimens, the four parameters decreased considerably after experiencing W-D cycles, while for the lime-stabilized specimens, they generally increased with an increase in the W-D cycles. Without experiencing the W-D cycles, the permeability coefficient increased by two times after it was stabilized with 10% lime. But with an increase in the W-D cycles, the permeability coefficient of the untreated and lime-stabilized specimens continuously increased and significantly decreased, respectively. Finally, variations in microstructure of the red bed soil under the effects of the lime stabilization and W-D cycles were discussed based on the SEM analysis. The results may contribute to improvement of red bed soil when used as roadbed and airfield fillings.

1. Introduction

Red beds are detrital sedimentary rocks that are widely distributed in tropical and subtropical areas all over the world [1, 2]. In China, the red beds are also widely distributed in southwest and northwest regions, with a total exposed area of approximately 0.826 million km² [3]. In natural conditions, most red beds generally demonstrate inferior geotechnical properties due to inclusion of clay and soluble and/or organic minerals [4]. Their lower strength, significant rheology, and a certain swelling property can cause various geological hazards and infrastructure damages [5]. Thus, when used as subgrade filling, the red beds need to be improved carefully either using physical or chemical methods [4, 5].

Lime is a prevalent and effective additive that has been widely used for soil stabilization. Previous studies showed that lime addition can increase the optimum water contents, shrinkage limits, and strengths of the mixtures but decrease the liquid limits, plasticity indexes, and maximum dry densities of the mixtures [6–13]. However, in engineering practice, there are lots of environmental conditions which can affect the effect of chemical stabilization of soil foundations. Due to alternation of wet and dry seasons, cyclic wetting-drying (W-D) is a very common phenomenon in shallow ground. Rao et al. [14] observed a negative effect of the W-D cycles on lime-stabilized and wood-ash-modified black cotton soil. Ye et al. [15] described variations in the unconfined compression strength and the Atterberg limits of expansive soils improved by industrial wastes with the W-D cycles. Wang et al. [16] showed that the strength of expansive soil improved by 0.3% OTAC (octadecyl trimethyl ammonium chloride)-3%KCL lost gradually with the W-D cycles. Guney et al. [17] investigated impacts of cyclic W-D on swelling behavior of lime-stabilized soil and found that the initial beneficial effect of lime stabilization was lost after the first W-D cycle. Akcanca and Aytekin [18] found that the beneficial effect of lime stabilization to control the swelling pressures of sand-bentonite mixtures would be partly lost by the W-D cycles, while in Yazdandoust and Yaarobi’s study [19], investigation on effect of cyclic W-D on swelling behavior of plymer-stabilized expansive clays showed that the beneficial effect of polymer stabilization would be preserved.

Till date, there exist limited studies regarding the impact of W-D cycles on the mechanical properties of lime-stabilized red bed soils. In this study, red bed soils taken from Northwest China were stabilized by lime with different ratios (0, 3, 5, and 10%), followed by exposure to different W-D cycles (0, 1, 5, and 20). Subsequently, unconsolidated-undrained triaxial tests, permeability tests, and SEM analysis were conducted to investigate the impact of W-D cycles on the mechanical properties of lime-stabilized soil. Based on these tests, effects of the W-D cycles on the stress-strain behavior, unconfined compressive strength and strength parameters, shear modulus, permeability, and microstructure were analyzed in detail. The obtained results may provide useful information for evaluating the long-term stability of foundation soils stabilized by lime in red bed areas.

2. Soil and Lime

The tested soil was taken from Chengzhou Airport (105°7′14.23″E, 33°75′31.75″N, and 1023 m a.s.l) in Chenxian Country, Gansu Province, at depths ranging from 2 to 5 m. The red beds were widely encountered within the depths. The disturbed soil was excavated, placed in plastic bags, and transported to the State Key Laboratory of Frozen Soil Engineering, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences.

The collected soil was air-dried, pulverized, and sieved to remove large particles. After that, the index properties of the red bed soil are tested and listed in Table 1. It can be seen that the free swell index was 45.5%. In the Specifications for Design of Highway Subgrades (JTG D30-2015) [20], soils are classified as nonexpansive (δ_ef ＜ 40), low expansive (40 ≤ δ_ef ＜ 60), medium expansive (60 ≤ δ_ef ＜ 90), and high expansive (δ_ef ≥ 90) based on the free swell index. Thus, the tested soil can be classified as low-expansive soil according to the specification.

The lime used in this study is commonly used hydrated lime (the major ingredient is Ca(OH)₂). At room temperature (about 20°C), the lime is a white crystalline powder with trace water.

3. Experimental Program

3.1. Specimen Preparation

Both the untreated and lime-stabilized specimens were prepared with the static compaction method specified in GB/T 50123–2019 [21]. According to previous studies on lime-stabilized soils [22], four ratios of added lime (RALs) (0, 3, 5, and 10% by the parent soil weight) and four different W-D cycles (0, 1, 5, and 20) were chosen in this study. All the test specimens were compacted at the respective maximum dry density and optimum moisture content. The height and diameter of the specimens were 80 mm and 39.1 mm, respectively. All the prepared specimens were wrapped with thin plastic film and stored in a curing box (20 ± 0.5°C, 96 ± 1% RH) for 28 days before the following W-D cycles.

3.2. W-D Cycles

A W-D cycle corresponds to a soil specimen being wetted and allowed to swell, followed by it being dried to its initial dry unit weight at an ordinary condition, then wetted again to swell, which is one W-D cycle. Here, the specimen was filled with water and allowed to fully swell for at least 24 h. Subsequently, the water was removed and the saturator was dismantled. The specimen was then allowed to air-dry at room temperature (about 20°C) to its initial dry unit weight. All dried specimens were carefully weighed before proceeding with the next W-D cycle. In this study, the W-D cycles that the specimens subjected to were 0, 1, 5, and 20, respectively. The pictures of the specimens after the wetting and drying are shown in Figure 1.

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3.3. Triaxial Test

Conventional undrained triaxial tests were conducted on the saturated untreated and lime-stabilized specimens using a strain-controlled system (ASTM D2850-15) [23]. The detailed diagram of the instrument and principle is shown in Figure 2. The confining pressures chosen in this study were 50, 100, and 150 kPa, and the strain rate was 0.8 mm/min. The maximum axial strain reached in a triaxial test was determined by the specimen failure mode. If the specimens failed in a strain-hardening mode, the maximum axial strain was 15%; however, if the specimens failed in a strain-softening mode, the maximum axial strain was 12%.

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3.4. Permeability Test

The falling head test was adopted in this study. The first step in carrying out the permeability test was to saturate the specimen in the mold. Afterwards, the subsequent saturation process and permeability test were carried out according to the Standard for Soil Test Method GB/T 20123–1999. The permeability coefficient was calculated aswhere a is the section area of variable head pipe (cm²); L is the specimen height(cm); A is the cross-sectional area of the specimen; and t₁ and t₂ are test start and end times, while H₁ and H₂ are test start and end water head.

3.5. SEM

SEM analysis was carried out on the parallel specimens to observe the variations in the soil structure after the lime addition and W-D cycles. The SEM equipment used was a Quanta250 electron microscope analysis system manufactured by the American FEI Technology company. Before the test, the prepared scanning specimen was first pumped to a vacuum state, and then the specimen surface was plated with gold. Subsequently, the scanned specimen was placed in Quanta250 for microstructure observation at magnifications of x100, x500, x1000 × 5000, and x10000 times.

4. Results and Analysis

4.1. Effect of W-D Cycles on Stress-Strain Behavior of Red Bed Soil

Stress-strain curves of the untreated and lime-stabilized specimens are presented in Figure 3. The stress-strain behavior of the untreated specimens mainly performed as strain-softening (Figures 3(a)–3(c)). However, after the peak, the reduction in the stress with further strain increase was not obvious. Meanwhile, the W-D cycle further weakened this strain-softening behavior. With the confining presses of 100 and 150 kPa, the stress-strain behavior of the untreated specimens changed to strain-hardening after 5 and 20 W-D cycles.

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The lime-stabilized specimens all performed as strain-softening (Figures 3(d)–3(l)), where the peak stress within these curves was obvious. After the peak, a significant stress reduction occurred as the strain increased further. When the strain reached 3–5%, the stress maintained and did not change considerably with any strain increase. Then, a residual strength was reached. It is known that the size of particles and the strength of cementation are very important for the soil strength [24]. The addition of lime leads to a series of chemical replacement reactions in the soil. The products from these reactions bind the soil particles around them together and strengthen the soils significantly [25, 26]. However, with the strain increase, the cementation provided by the cementation products breaks gradually. By comparing Figures 3(a)–3(c) and 3(d)-3(l), it can be seen that the residual strengths of the untreated and lime-stabilized specimens were very close. Thus, the stress reductions of the lime-stabilized specimens after the peak were significant. After the W-D cycles, the strain-softening behavior of the lime-stabilized specimens strengthened further. Compared with the untreated specimens, the failure strain of the lime-stabilized specimens decreased significantly.

4.2. Effect of W-D Cycles on the Shear Strength and Strength Parameters of Red Bed Soil

Variations in the shear strength of the untreated and lime-stabilized specimens with the W-D cycles are shown in Figure 4. It is evident that the W-D cycles had different effects on the shear strength of the untreated and the lime-stabilized specimens. For untreated specimens (Figure 4(a)), the shear strength decreased almost linearly with an increase in the W-D cycles. Without experiencing W-D cycles, the shear strength of the specimens ranged from 811 to 948 kPa under three confining pressures. After experiencing one W-D cycle, reductions in the shear strength all exceeded 20%. After 20 W-D cycles, the maximum reduction in the shear strength was as much as 60.5%.

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For the lime-stabilized specimens with 3% RAL (Figure 4(b)), the shear strength increased significantly compared to that of the untreated specimens. Without experiencing the W-D cycles, the shear strength of these specimens ranged from 1385 to 1757 kPa under three confining pressures, which was about two times that of the untreated specimens. Meanwhile, the shear strength increased with the W-D cycles and then decreased. After 5 W-D cycles, increases in the shear strength were as much as 163.2–183.6%. After 20 W-D cycles, although lower than that of the specimens experiencing 5 W-D cycles, the shear strengths were greater than those of the specimens that did not experience the W-D cycles.

While for the lime-stabilized specimens with RALs of 5% and 10% (Figures 4(c) and 4(d)), the shear strength increased further compared to that for the untreated soils. The greater the RAL was, the greater the increase in the shear strength was. For example, without experiencing W-D cycles, the lime-stabilized specimens with 10% RAL had their shear strength ranging from 1982 to 2342 kPa, which were 2.5 to 3 times that of the untreated specimens. Furthermore, with increasing the W-D cycles, the shear strength increased significantly. After 20 W-D cycles, the increase in the shear strength of the lime-stabilized specimens with 10% RAL was close to 200%.

Variations in the shear strength parameters of the untreated and lime-stabilized specimens with the W-D cycles are shown in Figure 5. It can also be observed that the W-D cycles had different effects on the shear strength parameters of the untreated and lime-stabilized specimens. For the untreated specimens, with increase in the W-D cycles, both the cohesion and the internal friction angle decreased considerably. After 20 W-D cycles, the maximum reductions in the cohesion and internal friction angle were 67.4% and 34.1%, respectively.

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While for the lime-stabilized specimens with all the three RALs, the cohesion first decreased and then increased with the increase of the W-D cycles. After 20 W-D cycles, increase in the cohesion of the lime-stabilized specimens ranged from 103.6% to 167.8%. On the other hand, the internal friction angle of the lime-stabilized specimens increased firstly and then decreased with the W-D cycles. With the RAL of 3%, the internal friction angle of the lime-stabilized specimens after 20 W-D cycles was smaller than that of the specimens without experiencing the W-D cycle. By contrast, when the RALs were 5% and 10%, the internal friction angle of the lime-stabilized specimens after 20 W-D cycles was still greater than that of the specimens without experiencing the W-D cycle.

4.3. Effect of W-D Cycles on the Shear Modulus of Red Bed Soil

The shear modulus is defined as the ratio of the deviatoric stress to the corresponding axial strain at an elastic deformation stage on the stress-strain curve. Based on the definition, the shear moduli of the untreated and lime-stabilized specimens are calculated and shown in Figure 6. To save space, only the results with the confining pressure of 100 kPa were presented. For the untreated specimens, the shear moduli decreased almost linearly with increase in the W-D cycles. After 20 W-D cycles, the maximum reduction was as much as 66.5%. Compared with that of the untreated specimens, the shear moduli of the lime-stabilized specimens increased considerably. Meanwhile, the greater the RAL was, the greater the increase in the shear modulus was.

Without experiencing the W-D cycles, the shear modulus of the lime-stabilized specimen with RAL of 3% was 65.3 Mpa. With increase in the W-D cycles, the shear modulus first increased and then decreased. After 5 W-D cycles, the increase in the shear modulus was 232.3%. Moreover, after 20 W-D cycles, the shear modulus was still greater than those specimens without experiencing the W-D cycles. For lime-stabilized specimens with the RALs of 5% and 10%, the shear moduli increased continuously with increase in the W-D cycles. Without experiencing the W-D cycles, the lime-stabilized specimen with RAL of 10% had its shear modulus being about 85.9 MPa. After 20 W-D cycles, the increase in the shear modulus was close to 500%.

4.4. Effect of W-D Cycles on Permeability of Red Bed Soil

Variations in the permeability coefficients of the untreated and the lime-stabilized specimens (10% RAL) with the W-D cycles are shown in Figure 7. For untreated specimens, the permeability coefficient increased significantly with an increase in the W-D cycles, which was 1.9 × 10⁻⁸ cm/s when there were no W-D cycles. After 5 W-D cycles, it increased by more than one order and reached up to 1.2 × 10⁻⁷ cm/s. This is because, with an increase in the W-D cycles, the quantity of free silt and clay particles progressively reduces as coarser particles are formed [27, 28], leading to larger void formations and an increase in permeability. By contrast, for lime-stabilized specimens with the 10% RAL, the W-D cycles had a different effect on the permeability coefficient. With an increase in the W-D cycles, the permeability coefficient of the lime-stabilized specimens decreased exponentially. After 5 W-D cycles, the permeability coefficient was only about 6.6 × 10⁻⁹ cm/s. The decrease in the permeability coefficient was related to the void filling by the production from the lime hydrate reaction with the silica or alumina.

4.5. Effect of W-D Cycles on Microstructure of Red Bed Soil

The SEM analysis is conducted on the untreated and lime-stabilized triaxial specimens after different W-D cycles to observe the effect of lime treatment and W-D cycles on morphological structure.

The SEM images of untreated specimens under different W-D cycles are shown in Figure 8. Without experiencing the W-D cycles, the structure of the soil particles was layered and lamellar with fewer voids. The specimens were relative dense. After the W-D cycles, the amount and size of the void increased gradually and the amount and size of large soil particles decreased. Then, the degree of aggregation of soil particles decreased considerably. The original layered and lamellar structures of the soil particle were broken, and the specimens became loose. These variations corroborate the decrease in the strength and the increase in the permeability of the specimens. The effects of W-D cycles on morphological structure above were also well confirmed by the mercury intrusion porosimetry test by Zeng et al. [29] and synchrotron-based X-ray microcomputed tomography tests and digital image analysis by Ma et al. [30].

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The SEM images of lime-stabilized specimens with RALs of 3% and 10% under different W-D cycles are shown in Figures 9 and 10. Without experiencing the W-D cycles, some honeycomb network structures among soil particles developed after the addition of lime and are clearly visible in Figures 9(a) and 10(a). The greater the RAL was, the more the honeycomb network structures developed were. Previous X-ray diffraction analysis indicated that cementitious compounds (e.g., CAH and CSH) formed from a serious of reactions between lime and soil [31–33]. Meanwhile, more voids were formed in soils as the soil particles were aggregated together. This agrees with the strength improvement of and the increase of the permeability of the specimens with addition of lime. When the RAL was 3%, the reactions went on with the increase in W-D cycles but almost finished after 5 W-D cycles. With further increase in the W-D cycles, the stability of the cementation among soil particles decreased, leading to a decrease in the strength of the specimens. While for the RAL of 10%, the reactions between lime and soil went on with the increase in W-D cycles. A great amount of aggregated soil particles formed from the honeycomb network structures and blocked the voids gradually. Thus, the permeability coefficient decreased with the increase in W-D cycles.

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5. Conclusions

The objective of this study was to investigate effects of the W-D cycles on the mechanical properties and microstructure of untreated and lime-stabilized red bed soils. Based on laboratory test results, the conclusions can be drawn as follows:(1)The untreated specimens mainly performed as weak strain-softening. After experiencing the W-D cycles, the strain-softening behavior of the untreated specimens was further weakened and even changed to strain-hardening under larger confining pressures. The lime-stabilized specimens all performed as strain-softening, and the stress reduction after the peak increased considerably after experiencing the W-D cycles.(2)Both the strength and permeability properties of the lime-stabilized specimens improved considerably. After experiencing the cyclic W-D, the shear strength, strength parameters, and the shear moduli of the untreated and lime-stabilized specimens decreased considerably and increased gradually, respectively. The permeability coefficient of the untreated and lime-stabilized specimens continuously increased and significantly decreased, respectively, with an increase in the W-D cycles.(3)SEM analysis demonstrated that the interior of the specimens changed from layered and lamellar structure to continuous honeycomb networking structure after lime stabilization. With an increase in the W-D cycles, the layered and lamellar broke step by step, and many dispersed structures formed. The honeycomb networking structure also gradually flocculated and aggregated into granular solids with the W-D cycles.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare no conflicts of interest.

Authors’ Contributions

Yuncheng Mao and Yanhu Mu conceived and designed the experiments. Zhengmin Song, Dewen Zhang, Kun Zhang, and Qinglong Zhang performed the experiments. Zhengmin Song analyzed the data and wrote the paper.

Acknowledgments

This work was supported by the Science and Technology Project of Gansu Provincial Transportation Department (no. 201600009), the Instrument Development Project of Chinese Academy of Sciences (no. 28Y928581), the Fund of the State Key Laboratory of Frozen Soil Engineering (no. SKLFSE201603), and the Science and Technology Project of Yalong River Hydropower Development Company (no. LHKA-G201701).

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Copyright © 2020 Zhengmin Song et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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