1. Introduction
Soils that exhibit volume-change upon variation of their moisture content are known as expansive soils. The swelling and shrinking nature of expansive soils is mostly attributed to the proportion of the clay mineral smectite in the soil, as well as the interaction of water with the clay mineral surfaces [
1]. The extent of swelling and shrinkage of expansive soils are also dependent on other factors such as soil suction, soil dry unit weight, stress-history, climate, and active zone depth [
2]. Expansive soils can prove to be especially hazardous in places with cycles of dry and wet spells resulting in repeated cycles of swelling and shrinkage. The effects of expansive soils are mostly observed near the ground surface where desiccation cracks can be seen in the dry season; further damages caused include pavement distress or failure, differential uplift or settlement of structures, slope and foundation failures, and other damages that compromise the integrity of infrastructures. Expansive soils are present all over the world and are ubiquitous in the south-western United States [
3,
4,
5,
6]. Millions of dollars are spent each year in the United States alone to fix damages caused to infrastructures by expansive soils [
3,
7,
8,
9,
10]. As such it is important to improve swelling and shrinkage characteristics of expansive soils before proceeding with infrastructure development.
Stabilization of expansive soils has been conventionally performed using chemical additives such as lime and cement, which have proven to significantly improve the strength and lower the volume-change behavior of expansive soils by a series of cationic exchange and pozzolanic reactions between the additive and soil particles [
11,
12,
13]. These calcium-based conventional chemical additives are known to have durability issues, in addition to having disadvantages in sulfate-rich soils, as certain chemical reactions result in the formation of the mineral ettringite, which causes excessive swelling and volume-change in soils [
14,
15]. The high demand of lime and cement additives has led to their mass production, which in turn reduces their unit cost, ultimately driving the low-cost production cycle. The cost benefits that lime and cement offer are progressively being overshadowed by their environmental implications. The production of lime and cement are energy-intensive operations that require kilns to be heated between 1000 °C to 1500 °C to process raw materials. A 2018 inventory of the greenhouse gas emissions by the Environmental Protection Agency (EPA) reported that lime and cement production industries produced 97 million metric tons of carbon dioxide (CO
2) from the minerals sector alone [
16]. As such, there is an imminent need to focus on sustainable alternatives or co-additives for lime and cement treatment works in pavement geotechnics.
The topic of sustainability is usually met with a lot of apprehension, as it is relatively new and can have a myriad of different interpretations. Nevertheless, Brundtland’s Declaration provides a widely recognized commentary which states that “sustainable development is development that meets the needs of the present without compromising the ability of future generations to meet their own needs” [
17,
18]. The prospect of integrating sustainability into a project is highest during the planning phase and diminishes considerably as the project moves into implementation phases [
19]. Since geotechnics is applied in the early stages of a project, it renders an advantage and responsibility to implement sustainable geotechnical practices that positively influence the subsequent phases of infrastructure development. The engineering perspective of sustainability often incorporates cost-efficiency and reasonable control of harmful emissions, in addition to prudent resource consumption [
20,
21]. Therefore, a comprehensive sustainability approach includes environmental protection, economic development, and social development [
18]. Regrettably, environmental impacts have been sidelined for far too long for the sake of monetary benefits, and therefore need to be addressed with more weightage for constructive sustainability with lasting positive impacts.
In recent years, a new class of binder materials known as geopolymers have been hailed as a more sustainable and eco-friendly alternative to lime and cement, due to comparable compressive strength, durability, and low shrinkage properties [
22,
23,
24]. Geopolymers are aluminosilicate polymers that can be synthesized from industrial by-products, such as metakaolin, fly ash, and clay [
25,
26,
27,
28], relatively quickly at ambient temperatures thereby having a significantly lower carbon footprint than lime or cement binders [
29,
30]. Geopolymers consist of extensive three-dimensional structures of covalently bonded aluminosilicates formed by the alkali activation of aluminosilicate rich materials [
24]. They are essentially rigid gels that may evolve to form amorphous or crystalline materials under certain temperature and pressure conditions [
31]. Chemically, geopolymers can be classified as polysialates and can be represented by their empirical formula as shown in Equation (1) [
25].
where, M is the alkali metal cation (such as Na, K, or Ca), n is the degree of polycondensation, z is the silicon to aluminum (Si:Al) ratio (usually 1, 2, or 3), and w is the molar water amount. Geopolymers are formed in a high pH environment through an alkali-activated polycondensation reaction comprising of five stages—dissolution, speciation equilibrium, gelation, reorganization, and polymerization and hardening [
10,
24,
32]. The synthesis of geopolymers requires an aluminosilicate-rich source (metakaolin, fly ash), an alkali-metal cation source (such as NaOH, KOH, or Ca(OH)
2), an additional source of silica (as needed), and water. Predetermined ratios of the components are mixed to form a slurry which on curing form a hardened geopolymer. The transformation of the slurry to form the hardened geopolymer is the result of overlapping polycondensation reactions of the dissolved aluminosilicate species in an aqueous solution resulting in their subsequent polymerization, gelation, and hardening [
33]. The gelation of different aluminosilicate species and characteristics of their respective geopolymer formations are dependent on various factors such as concentration of reactive species in solution, raw material type and quality, water content, curing conditions, and time [
29,
34,
35]. Recent studies have shown that metakaolin-based geopolymers significantly improved the strength and volume-change properties of expansive soils [
10,
33,
36,
37].
The focus of this study is to assess the sustainability benefits of the metakaolin-based geopolymer used by the authors to successfully treat a high plasticity expansive clayey soil [
10,
33]. The sustainability benefits of the metakaolin-based geopolymer in this study were evaluated based on the sustainability framework developed at University of Texas at Arlington, which utilizes a weighted multi-criterial evaluation based on resource consumption, environmental impact, and socio-economic impact [
18]. Additionally, sustainability benefits were assessed for the conventional lime treatment of the same clay.
3. Sustainability Benefits Assessment Framework
The assessment of sustainability benefits of the metakaolin-based geopolymer in this study was performed by the estimation of the sustainability index (I
Sus) as per the framework recently introduced at University of Texas at Arlington [
18,
42]. The I
Sus of a material is proposed to be a function of its resource consumption, environmental impact, and socio-economic impact, and is estimated as shown in Equation (3):
where, I
Rec is the resource consumption index, I
Env is the environmental impact index, I
SoEc is the socio-economic impact index, and W
1, W
2, and W
3 are the weighted values of each associated index. The weighted values assigned for each index provide an insight into their relevance for a specific project and can be varied based on the executor’s judgement. The I
Sus can be estimated for different materials for a comparison of the values, with the material with the lowest I
Sus being the most sustainable. Life cycle assessment (LCA) is an essential process of obtaining the resource consumption and environmental impact aspects of the sustainability index. The following paragraphs describe the impact factors used in this study to determine the I
Sus.
Resource consumption was determined using energy accounting methods during life cycle inventory (LCI) analysis, which is a subset of LCA. The I
Rec was estimated using the embodied energy of materials using a “cradle to gate” approach which accounts for the energy expended during the process of production and transportation of materials. The embodied energy of materials used in the study were obtained from the literature [
43] and is reported in megajoules (MJ).
Environmental impact assessment is a function of three major components—global warming potential, acidification potential, and eutrophication potential. The global warming potential (GWP) is an estimate of the impact of raw materials and manufacturing processes on the production of greenhouse gases, which consequentially raises the average global temperature. In this study, the GWP was represented by the amount of carbon dioxide produced contributing to global warming and is reported in gram equivalent of CO2 (gCO2 eq.). The acidification potential (AP) is the ability of a material to raise the acidity of soils or nearby water bodies by decreasing its pH and is measured in gram equivalent of SO2 (gSO2 eq.). Increased AP usually deposits itself in the form of acid rain, which is known to have harmful effects on living beings as well as infrastructure. The eutrophication potential (EP) is an indicator of biodiversity and ecological health and is measured in gram equivalent of PO43− (gPO43− eq.). An increase in EP or over-nutrification is usually evident in aquatic systems by algal blooms that cause oxygen deficiency, leading to the death of other aerobic organisms, thereby disrupting the biodiversity of adjoining ecosystems.
A cost-benefit analysis is used to evaluate the socio-economic impact index (I
SoEc) of different materials that can be used for a project. A life cycle costing (LCC) is used to quantify costs associated with each alternative usually including purchase, construction, operation, maintenance, rehabilitation, and other residual costs [
18]. Weighted values are applied to the different categories used to calculate each of the indices, based on their relevance for the project A flowchart of the sustainability benefits assessment framework is shown in
Figure 7. This was a pilot study of the sustainability benefits of geopolymers as soil stabilizers and therefore focused on the initial cost of materials.
4. Comparative Sustainability Benefits
Sustainability benefits were assessed for a laboratory-scale scenario comparing geopolymer and conventional lime treatment of the high-plasticity Lewisville clay (CH). The assessment was performed for dosages of 10% MK for geopolymer treatment and 8% lime for lime treatment of the soil. The appropriate dosage of lime required to stabilize CH was determined based on the Eades and Grim pH test as per TEX 121-E, as well as the soluble sulfate content. In this study, I
Sus was evaluated for the primary components of both treatment methods for the same quantity of dry soil (100 kg). As such, this assessment analyzes the sustainability characteristics of metakaolin alone for the geopolymer treatment of soils, as other ingredients (silica fume, KOH) were utilized in lower quantities. Conventional soil treatment of the high plasticity Lewisville clay was performed using commercially available lime. The summary of the treatment methods assessed for sustainability are provided in
Table 2:
As explained earlier, the I
Sus was determined using indices for resource consumption, environmental impact, and socio-economic impact for metakaolin and lime. The embodied energy values for production of metakaolin, as well as its potential for global warming, acidification, and eutrophication were obtained from published literature [
43]. The values for embodied energy used during the production of lime, and its acidification and eutrophication potential were obtained from previous studies [
44]. The global warming potential of lime was obtained from the Inventory of Carbon and Energy (ICE) database [
45]. Additionally, the embodied energy from transportation of materials from source to site was determined from the GREET (Greenhouse gases, Regulated Emissions, and Energy use in Transportation) model [
46] developed by Argonne National Laboratory.
The resource consumption of both treatments based on the embodied energy consumed during their production and transportation are summarized in
Table 3. The I
Rec for the treatment methods were estimated using Equation (4) [
18]:
where, w
1a, w
1b, w
1c are weighted values of each parameter and E
E is the embodied energy. The embodied energy consumed due to transportation of both materials was estimated to be 1.5 MJ/metric ton-km [
46], assuming a source to site distance of 80 km (50 miles) covered by a truck. The significantly higher consumption of resources per kg of lime than geopolymer is highlighted by placing higher weighted values on the embodied energy of lime. The resource consumption of Treatment A is observed to be lower than Treatment B with a lower I
Rec value of 46.67.
The comparison of environmental impact indices of both treatments is presented in
Table 4, where I
Env was calculated as per Equation (5) [
18]:
where, w
2a, w
2b, w
2c are weighted values of each parameter. The ever-increasing and unimpeded carbon dioxide emissions pose a more imminent concern on a global scale; therefore, higher weightage values were assigned for the GW
P of both treatments than its A
P and E
P.
Table 4 shows Treatment A to have a significantly lower I
Env value of 38.73 than Treatment B.
The socio-economic impact of the treatments was estimated based on the average unit price of lime obtained from manufacturers and are presented in
Table 5. The unit price of the conventional Treatment B was found to be 0.12 USD per kg [
47], and the unit price of the novel Treatment A was assumed to be 50% more than the unit price of Treatment B. Note that the actual unit price of Treatment A is significantly higher and it can be attributed to low demand. The higher cost contribution of Treatment A is attributed to the higher unit price of the novel Treatment A compared to the low unit price of the mainstream Treatment B, in addition to the higher quantity of novel material required for soil treatment. The I
SoEc was calculated using Equation (6) as [
18]:
where w
3 = 1.0, and C is the total cost of treatment. Treatment B was found to have a lower socio-economic impact with a lower I
SoEc value of 34.78.
Finally, the I
Sus of both treatments was calculated by adding the weighted values of the three indices as shown in Equation (1) and is summarized in
Table 6. For the calculation of I
Sus, both the I
Rec and I
Env were assigned a weight of 40% while, the I
SoEc was assigned a lower weight of 20%, since current cost estimates need to be further adjusted based on future supply and demand, in addition to cost being a secondary aspect of this study. According to the sustainability benefits assessment, Treatment A (geopolymers) is deemed a more sustainable alternative with a lower I
Sus value than using Treatment B (lime) for soil improvement. It is important to note that the weighted values applied to each of the indices calculated are left to the discretion of the user. The weighted values will vary significantly for each project and will need to be verified by the user to be reliable and meaningful for the respective application and expected end-goal. The sustainability assessment framework can be used to effectively compare different alternatives for a project, to determine the most sustainable alternative.
Figure 8 shows a graphical representation of the different aspects of the sustainability benefits assessment. It is to be noted that the radar chart does not reflect the unequal individual weights applied to each of the parameters to evaluate the indices [
18]. The structural integrity characteristics representative of resiliency, namely probability of fatigue cracking and rutting failure, are also included in this radar chart for a better comparison of both treatments. The hypothetical pavement section and design system used for evaluating the resiliency characteristics have been described in detail in [
33]. From
Figure 8, the area under geopolymer treatment was estimated to be about 0.64 square units, while it was larger for lime treatment with an estimate of 0.86 square units. Therefore, Treatment A (geopolymer) is confirmed to be a more sustainable alternative than Treatment B (lime) based on the assumptions of the sustainability benefits assessment elaborated in this study.