Your search keyword '"CLAY soils"' showing total 18 results

1. Soil stabilization using Granulated Blast Furnace Slag (GBFS), lime & bagasse ash.

Author

Zahoor, Sabah and Sharma, Tarun

Subjects

*SOIL stabilization, *BAGASSE, *INDUSTRIAL wastes, *CLAY soils, *SLAG

Abstract

Since clayey soils are highly plastic therefore they are unstable for the purpose of construction. These soils continuously keep on changing temporarily or permanently once they come in contact with water. Soil stabilization is a process of enhancing the properties of soil especially from engineering point of view. This literature review scientifically scrutinizes the functioning features of clayey soils made using industrial wastes such as lime, Granulated Blast Furnace Slag(GBFS) and bagasse ash. The organized exploration was incorporated from Web of Science and SCOPUS by means of altered keywords, and 111paperworkshave been recognized. Following the screening and suitability progression in consistency with PRISMA guidelines, 30 papers have been chosen carefully and hence chosen to be assessed and explored. Here the working features of the soil keeping in view the physical properties, mechanical properties, durability criteria, microstructural examination, statistical examination, cost determination, etc. were scrutinized. Most of the studies using different industrial wastes in soil stabilization have seen to be emphasizing on determining the compressive strength, water absorption, Atterberg's Limits, strength and durability by wetting drying cycles. The PH, electrical conductivity, maximum dry density and optimum water content, thermal conductivity, tensile strength, and flexural strength have also been assessed in latest studies and recounted in this paper. The research papers used industrial wastes such as lime, GBFS, bagasse ash etc and conducted several tests for each of the materials like unconfined compressive strength(UCS), compressibility indices, Atterberg's limit, indirect tensile strength, flexural strength, split tensile strength, California Bearing ratio(CBR) test, Scanning Electron Micrograph (SEM) test, SPC test, and many more tests and microstructural analysis during the stabilization of clayey soil via distinctive industrial wastes for advanced findings found to be short of in existing writings. [ABSTRACT FROM AUTHOR]

Published

2024

2. Stabilization of Clayey Soil with Alkali-activated Hybrid Slag/Cement.

Author

Yıldırım, Eray, Bol, Ertan, Avcı, Eyübhan, and Özocak, Aşkın

Subjects

*CLAY soils, *SOIL stabilization, *SLAG, *CEMENT, *PORTLAND cement, *SOLUBLE glass

Abstract

This study investigates the stabilization performance of clayey soil treated with alkali-activated hybrid slag/cement. Sodium silicate (SS) and sodium hydroxide (SH) are used as alkali activators, whereas ground blast furnace slag (GGBS) and ordinary Portland cement (OPC) are used as sources of aluminosilicate. A total of 27 different types of mixtures are used for stabilization. Unconfined compressive strength (UCS) of untreated clay and stabilized soils are performed at immediately, 3-, 7-, 28-, and 90 days curing times under air-dried and wet-cured conditions. In addition, 90-d volume and mass changes in the samples are measured. Stabilized samples with an SS/SH ratio of 1 under air-dried conditions reveal moistening at early curing ages (=28 days); afterward, sodium carbonate crystals appear in these samples at longer curing ages. Geopolymer-treated clayey soil exhibits lower volumetric and mass changes compared with OPC. Most of the stabilized clayey soil with alkali-activated hybrid slag/cement exhibits higher strength compared with OPC under air-dried and wet-cured conditions. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of addition of ground granulated blast furnace slag (GGBFS) as clay soil stabilization material with CBR test and unconfined compression test.

Author

Roesyanto and Panggabean, Putri Luki Mega Lestari

Subjects

*CLAY soils, *SOIL stabilization, *MATERIALS testing, *SLAG, *SPECIFIC gravity

Abstract

Clay soil consists of tiny and submicroscopic-sized particles with a grain width of less than 0.002 mm that have been weathered because of chemical reactions. Because clay soil can inflate and shrink, it can be stabilized. Soil stabilization is the process of combining soil with specific materials to improve the technical and mechanical qualities of the soil to meet specific technical standards. In this study, we will look at how adding Ground Granulated Blast Furnace Slag (GGBFS) with various combinations as a stabilizing agent can improve physical and mechanical qualities such as CBR value and unconfined compression test, so that the clay soil can fulfill the specifications for field compaction. According to the AASHTO classification system, the clay soil was classified as A-7-6 (11), and according to the USCS classification system, it was classified as CH (Clay – High Plasticity). The original soil sample was found to have a moisture content of 62.50 percent, a specific gravity of 2.59, a liquid limit of 60.82 percent, a plastic limit of 24.38 percent, and a plasticity index of 36.44 percent, according to the study. The original soil's unsoaked CBR Laboratory value was 5.62 percent, and the actual soil's unconfined compression strength was 1.15 gr/cm2. With a 14-day curing period and a 35 percent GGBFS addition, the maximum value for unsoaked CBR was 16.52 percent, and the unconfined compression strength was 2.46 gr/cm2. [ABSTRACT FROM AUTHOR]

Published

2023

4. Strength performance of low-bearing-capacity clayey soils stabilized with ladle furnace slag.

Author

Espinosa, Ana B., Revilla-Cuesta, Víctor, Skaf, Marta, Serrano-López, Roberto, and Ortega-López, Vanesa

Subjects

CLAY soils, COHESION, SOIL cohesion, BEARING capacity of soils, SLAG, SOIL stabilization

Abstract

In this paper, the performance of ladle furnace slag (LFS), a by-product of secondary steel refining, is evaluated as a binder to stabilize clayey soils of low bearing capacity. The aim is to define whether additions of this by-product to clayey soil can stabilize the soil in accordance with the technical specifications of Spanish standards. To do so, three different soils stabilized with 5% LFS were compared with the same soils stabilized with 2% lime and with no stabilization, in order to investigate their different behaviors. The chemical and mineralogical characterizations of all the soil mixes were conducted using X-ray fluorescence, X-ray diffraction, and scanning electron microscopy. The Atterberg limit test was used to study the plastic behavior of the soils, and the results of compaction, bearing capacity, unconfined compressive strength, and direct shear strength (cohesion and friction angle) tests defined their strength characteristics. The analysis was completed with the pH monitoring of the mixes along the curing time in order to relate the pH changes with the strength evolution. The addition of LFS to the soils has resulted in an increase in the liquid limit and plastic limit, causing therefore a slight decrease in the plasticity index. All the soils showed increases between 30% and 70% in their California Bearing Ratios immediately after mixing with 5% LFS, and after 90 days of curing, improvements of 30–188% in their unconfined compressive strength were noted in comparison with untreated soil, which were higher than the lime-stabilized soils. The cohesion of soils stabilized with LFS at 28 days of curing obtained improvements ranging from 40 to 300% depending on the type of soil. However, the friction angle showed a slight increase of 10% in two of the soils and zero in another. The high initial pH in LFS-stabilized soils was maintained during the curing time, which favored the development of pozzolanic reactions that improve the soil strength. These results confirmed that the substitution of lime with LFS is a feasible option for soil stabilization. [ABSTRACT FROM AUTHOR]

Published

2023

5. Amelioration Effect of Fly Ash and Powdered Ground Steel Slag for Improving Expansive Subgrade Soil.

Author

Alemshet, Dereje, Fayissa, Basha, Geremew, Anteneh, and Chala, Gelata

Subjects

SWELLING soils, FLY ash, SOIL stabilization, SLAG, SCANNING electron microscopes, CLAY soils

Abstract

The utilization of fly ash (FA) and powdered granulated steel slag (PGSS) as additives in soil stabilization plays a crucial role in environmental, economic, and weak soil property improving advantages. In this study, the combined effect of FA and PGSS in improving expansive subgrade soil was investigated. The materials used for this study were expansive soils, FA, and PGSS. The study has applied an experimental research method. For this investigation, the index properties, Free Swell Index (FSI), unconfined compressive strength (UCS), optimum moisture content (OMC), California bearing ratio (CBR), and scanning electron microscope (SEM) tests were done for treated and untreated expansive soils. The findings indicated that as the mixture of FA (0 to 12.5% at 5% increment) and PGSS (0 to 25% at 5% at 2.5% increment) is added to the untreated expansive soils, the index properties, FSI, and OMC of the soils were significantly declined. The CBR values of expansive soils containing 20% FA and 10% PGSS mixture were 13.8% and 16.21%, respectively, which improved the quality of the soils by 85.43% and 84.82%, respectively. While the untreated expansive soils have a UCS value of 0.34 kg/cm2, the treated soil comprising 20% FA and 10% PGSS mixture has a UCS value of 13.42 kg/cm2, indicating that the soil strength is enhanced by 97.47%. The results of the studies demonstrate that adding FA and PGSS to expansive soil improves its stability and strength. The study concluded that disposals such as FA and PGSS might be effectively used in enhancing the characteristics of construction materials and used for the construction. [ABSTRACT FROM AUTHOR]

Published

2023

6. Effects of binder types and other significant variables on the unconfined compressive strength of chemical-stabilized clayey soil using gene-expression programming.

Author

Pham, Van-Ngoc, Oh, Erwin, and Ong, Dominic E. L.

Subjects

*CLAY soils, *COMPRESSIVE strength, *SOIL moisture, *FLY ash, *CLAY, *SILT, *SLAG, *SOIL stabilization

Abstract

Soil stabilization is an in situ soil treatment in which soils are mixed with cementitious or other chemical stabilizing agents. Determining the unconfined compressive strength (UCS) of stabilized soil is a principal task in the design and construction of the ground improvement. Hence, this study aims to develop a reliable predictive model for the UCS of clay stabilization with common cementitious binders using the gene-expression programming (GEP) technique. Eleven parameters, including the soil characteristics, the binder types, the binder contents, the mixing method, and the curing period, were considered as the independent variables in the model. The research results show that the selected optimal GEP-based model performs well with an acceptable correlation coefficient (R = 0.951) and low errors (e.g., RMSE and MAE). Besides, parametric analyses indicate that the plastic index, the percentage of clay, and the total water content have a negative effect on the UCS of stabilized soil. In contrast, the percentage of silt and sand, the binder types, the binder contents, and the curing time show a positive effect on the strength of stabilized soil. In addition, the strength of stabilized clay could be significantly enhanced by combining cement with slag, lime, or fly ash with a reasonable ratio, or by reducing the natural water content in the soil. The research findings could help engineers choose suitable binder types and cost-effective methods to optimize the UCS of stabilized clay. [ABSTRACT FROM AUTHOR]

Published

2022

7. Improving the Properties of Soft Clay Using Cement, Slag, and Nanosilica: Experimental and Statistical Modeling.

Author

Eissa, A., Bassuoni, M. T., Ghazy, A., and Alfaro, M.

Subjects

*SLAG cement, *SLAG, *CLAY soils, *CLAY, *STATISTICAL models, *CEMENT, *SOIL stabilization

Abstract

Efficient utilization of problematic soils such as soft clay by imparting additional strength using various stabilization techniques is done to improve soil properties. The application of nanomaterials in the area of soil stabilization has great potential to create a stiff skeleton, especially when blended with cementitious materials. Using the response surface method, this study focused on studying the effects of single and blended cementitious systems, comprising cement (0% to 20%), slag (0% to 20%), and nanosilica (0% to 2.4%), on the properties of soft clay in wet conditions [water-to-soil ratio (w/s) of 53% to 87%]. The mechanical [California bearing ratio (CBR), unconfined compressive strength up to 91 days] and durability (freezing-thawing durability factor) properties of stabilized clay were investigated, and the bulk trends were corroborated by thermogravimetry and microscopy analyses. Based on statistical analysis, incremental addition of cement, slag, and nanosilica led to the systematic increase in the properties of soft clay, albeit to different extents and with different mechanisms. At the low w/s (53%), superior mechanical and durability properties were obtained for soft clay stabilized with the ternary binder comprising cement, slag, and nanosilica. Numerical optimization showed that stabilizing this weak type of soft/expansive clay is possible, but the results (proportions, performance, cost) varied based on the target design criteria and application. [ABSTRACT FROM AUTHOR]

Published

2022

8. Sustainable soil stabilisation with ground granulated blast-furnace slag activated by olivine and sodium hydroxide.

Author

Fasihnikoutalab, Mohammad Hamed, Pourakbar, Shahram, Ball, Richard J., Unluer, Cise, and Cristelo, Nuno

Subjects

*SODIUM hydroxide, *OLIVINE, *SLAG, *CLAY soils, *SOILS, *SOIL stabilization

Abstract

Ground granulated blast-furnace slag (GGBS), activated with olivine (Mg2SiO4) and sodium hydroxide (NaOH), was used to stabilise a clayey soil. Mechanical and microstructural properties of the stabilised soil were assessed through uniaxial compression strength (UCS) tests, X-ray diffraction, scanning electron microscopy and energy-dispersive X-ray spectroscopy (EDS), after curing periods of 7, 18 and 90 days. The UCS of the GGBS-treated soil (without activation with NaOH), even at the highest slag dosage (G20S), after 90 days, showed only a slight increase (142 kPa) relatively to the original soil. When olivine was added to the GGBS-treated mixture (O20G20S), the UCS increased to 444 kPa, after 90 days. However, when NaOH was used as an activator, the UCS of the olivine–GGBS-treated soil (NO20G20S) increased to more than 6000 kPa, after 90 days. This significant strength increase was attributed to the higher reaction degree provided by the NaOH, which enabled a more effective exploitation (dissolution) of the Ca and Mg present in the slag and olivine, respectively, forming a mixture of C–S–H and M–S–H gels. [ABSTRACT FROM AUTHOR]

Published

2020

9. Using Steel Slag for Stabilizing Clayey Soil in Sulaimani City-Iraq.

Author

Zozk Kawa Abdalqadir, Nihad Bahaaldeen Salih, and Soran Jabbar Hama Salih

Subjects

CLAY soils, SLAG, SOIL mechanics, SPECIFIC gravity, STEEL, SOIL stabilization

Abstract

Copyright of Journal of Engineering (17264073) is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

10. Study of the expansive behavior of ladle furnace slag and its mixture with low quality natural soils.

Author

Montenegro-Cooper, J.M., Celemín-Matachana, M., Cañizal, J., and González, J.J.

Subjects

*SLAG, *SOIL leaching, *MAGNESIUM oxide, *EMBANKMENT design & construction, *CHEMICAL reactions, *CLAY soils

Abstract

Highlights • Analysis of soil-slag mix interactions with expansion and leaching tests. • Magnesium oxide content a predictor of long-term slag expansion. • Mathematical modeling accurately predicts potential ladle furnace slag expansion. • Expansion of soil-slag mixes less than in each individual material. Abstract Volumetric expansion tests are performed on both ladle furnace slag and mixtures with natural soils, with a view to their use in civil engineering projects such as embankment construction and related earth works. The study provides an analysis of the effects of magnesium oxide and proposes an analytical model to predict LFS expansion within shorter time frames than the potential expansion tests specified in the ASTM D 4792 standard. It was found that major chemical reactions between the mixture of clayey soils and the slag occurred in the first 40 h of the potential expansion test. An acceptable relationship was also established between the values of the potential expansion test and the CBR swelling test described in ASTM D 1883. [ABSTRACT FROM AUTHOR]

Published

2019

11. Mechanical Behavior and Sulfate Resistance of Alkali Activated Stabilized Clayey Soil.

Author

Singhi, Binod, Laskar, Aminul, and Ahmed, Mokaddes

Subjects

CLAY soils, PAVEMENT design & construction, CEMENT, LIME (Minerals), GEOTECHNICAL engineering

Abstract

Clayey subgrade soil requires treatment in order to make the subgrade stable for pavement structures. Treatment of clayey soil i.e. stabilization of clayey soil by cement, lime, and fly ash are established techniques used in geotechnical and highway engineering. Stabilization by alkali activation of fly ash is reported recently but literatures are limited. Present study investigates the stress strain behavior, peak stress and ultimate strain of clayey soil stabilized by slag and slag-fly ash blending by alkali activation. The peak stress as high as 25.0 N/mm may be obtained at 50% slags content when 12 molar sodium hydroxide solutions were used. Peak stress, ultimate strain and slope of stress-strain curve of stabilized clay are controlled by Na/Al and Si/Al ratios. Stress-strain response and peak stress of slag and fly ash blended specimen are not governed by Na/Al and Si/Al ratios; rather the behavior is dependent predominantly on slag content. [ABSTRACT FROM AUTHOR]

Published

2017

12. Stabilization treatment of a dispersive clayey soil using granulated blast furnace slag and basic oxygen furnace slag.

Author

Goodarzi, A.R. and Salimi, M.

Subjects

*CLAY soils, *BLAST furnaces, *BASIC oxygen furnaces, *SLAG, *WASTE products, *SOIL stabilization, *FLOCCULATION

Abstract

Dispersive clays may pose considerable distress if not adequately taken care of. On the other hand, the treatment of problematic soils with waste materials has been recently proved to be a useful option from economic and environmental view point. Hence, in this research, the potential use and effectiveness of dispersive soil stabilization using two types of industrial by-product, including granulated blast furnace slag (GBFS) and basic oxygen furnace slag (BOFS) were investigated. The slags were separately added (ranging from 2.5 to 30%) to a laboratory dispersed sample and a set of experiments were performed to study the physicochemical, mechanical and microstructural changes of the stabilized soil. The results indicate that the soil dispersion can be eliminated upon adding 10% BOFS. This is attributed to the exchange of interlayer sodium ions on the clay surfaces by multivalent cations from the agent. Besides, an increase in the ion concentration of soil-additive mixtures induces a more depression of the diffuse double layer that decreases the soil dispersivity potential. With increasing the curing time, an improvement in the strength of composite samples is observed. The formation of cementitious compounds due to the pozzolanic reactions is responsible for such a treatment, as confirmed by the XRD analyses and SEM micrographs. It appears that the GBFS has a lower activity as compared to BOFS, therefore causes less influence on the soil engineering parameters and a higher percentage (20–25%) of GBFS is required to govern soil dispersion. Overall, utilization of the studied slags particularly of BOFS is very effective to overcome the problems associated with dispersive soils. [ABSTRACT FROM AUTHOR]

Published

2015

13. A LABORATORY STUDY ON THE EFFICACY OF GRANULATED BLAST FURNACE SLAG AS AN ADMIXTURE FOR IMPROVING THE STRENGTH CHARACTERISTICS OF THE KAKINADA MARINE CLAY.

Author

Koteswara Rao, D., Prasada Raju, G. V. R., and Raghavendra Kumar, G. V.

Subjects

SLAG, CLAY soils, SOIL stabilization, CEMENT admixtures, INDUSTRIAL waste & the environment

Published

2011

14. Potential of Soil Stabilization Using Ground Granulated Blast Furnace Slag (GGBFS) and Fly Ash via Geopolymerization Method: A Review.

Author

Abdila, Syafiadi Rizki, Abdullah, Mohd Mustafa Al Bakri, Ahmad, Romisuhani, Burduhos Nergis, Dumitru Doru, Rahim, Shayfull Zamree Abd, Omar, Mohd Firdaus, Sandu, Andrei Victor, Vizureanu, Petrica, and Syafwandi

Subjects

*FLY ash, *INDUSTRIAL wastes, *SLAG, *CLAY soils, *ROAD construction, *SOIL stabilization

Abstract

Geopolymers, or also known as alkali-activated binders, have recently emerged as a viable alternative to conventional binders (cement) for soil stabilization. Geopolymers employ alkaline activation of industrial waste to create cementitious products inside treated soils, increasing the clayey soils' mechanical and physical qualities. This paper aims to review the utilization of fly ash and ground granulated blast furnace slag (GGBFS)-based geopolymers for soil stabilization by enhancing strength. Previous research only used one type of precursor: fly ash or GGBFS, but the strength value obtained did not meet the ASTM D 4609 (<0.8 Mpa) standard required for soil-stabilizing criteria of road construction applications. This current research focused on the combination of two types of precursors, which are fly ash and GGBFS. The findings of an unconfined compressive strength (UCS) test on stabilized soil samples were discussed. Finally, the paper concludes that GGBFS and fly-ash-based geo-polymers for soil stabilization techniques can be successfully used as a binder for soil stabilization. However, additional research is required to meet the requirement of ASTM D 4609 standard in road construction applications, particularly in subgrade layers. [ABSTRACT FROM AUTHOR]

Published

2022

15. Düşük Plastisiteli Bir Kilde Katkı Olarak Çelikhane Curufunun Kullanılması ve Kireç ile Etkileşimi.

Author

Bilgen, Gamze, Kavak, Aydin, and Çapar, Ömer Faruk

Subjects

SLAG, CLAY soils, MATERIAL plasticity, STEEL, SOIL stabilization, COMPACTING

Abstract

Copyright of Karaelmas Science & Engineering Journal / Karaelmas Fen ve Mühendislik Dergisi is the property of Karaelmas Science & Engineering Journal and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2012

16. Strength performance and microstructural evolution of carbonated steel slag stabilized soils in the laboratory scale.

Author

Yu, Chunyang, Cui, Chunyi, Wang, Yu, Zhao, Jiuye, and Wu, Yajun

Subjects

*SLAG, *CLAY soils, *CLAY minerals, *SOILS, *STEEL, *SOIL stabilization, *MONTMORILLONITE

Abstract

The technique of carbonated stabilization is an innovative method to improve the engineering performance of soft soils. However, the improvement in the engineering performance of stabilized soils with carbonized steel slag has not been studied. In addition, the effect of clay minerals on carbonation parameters and D-W cycle performance remains unknown. To this end, in this paper, three types of synthetic soils containing different clay minerals were prepared to be stabilized by carbonated steel slag. The strength performance and microstructural evolution of carbonated steel slag stabilized soils were investigated by drying-wetting (D-W) cycle tests, unconfined compression strength (UCS) tests, X-ray diffraction (XRD), thermogravimetry (TG), and scanning electron microscopy (SEM). The results showed that the compressive strength after and resistance to D-W cycles of carbonated steel slag stabilized soils were significantly improved due to carbonation treatment. The presence of clay minerals in stabilized soils led to the high values of optimum moisture content for carbonation (C-OMC). The C-OMC value of stabilized soils containing montmorillonite was higher than that of stabilized soils containing kaolinite. Montmorillonite had a higher negative effect on the D-W cycle performance of soils compared to kaolinite. This fact could be reflected by the fluctuation of UCS and mass change ratio (R m). The main carbonation product by three types of carbonated steel slag stabilized soils was calcite, which remained stable after D-W cycles. After carbonation for 18 h, the generated calcite and carbonation degrees for three types of stabilized soils were obtained. In the microstructures of carbonated steel slag stabilized soils, the spindle-like clusters of the generated calcite appeared, which adhered to the surface of mineral particles. The aggregated degrees of the generated calcite in stabilized soils containing clay minerals tended to decrease after D-W cycles. In this work, a new type of carbonated steel slag stabilized soil was studied. The results indicated that the effect of clay minerals on the engineering characteristics of soil should be considered. • Carbonated steel slag is used to stabilize three types of artificial soils. • Influence of clay minerals on performance and microstructure of carbonated steel slag stabilized soils is investigated. • The existence of clay minerals leads to increasing values of the optimum moisture content for carbonation. • The main carbonation product is calcite which remains to be stable after drying and wetting cycles. [ABSTRACT FROM AUTHOR]

Published

2021

17. Stabilization of a Clayey Soil with Ladle Metallurgy Furnace Slag Fines.

Author

Brand, Alexander S., Singhvi, Punit, Fanijo, Ebenezer O., and Tutumluer, Erol

Subjects

*LADLE metallurgy, *CLAY soils, *SOIL stabilization, *FURNACES, *SLAG, *CALCIUM chloride

Abstract

The research study described in this paper investigated the potential to use steel furnace slag (SFS) as a stabilizing additive for clayey soils. Even though SFS has limited applications in civil engineering infrastructure due to the formation of deleterious expansion in the presence of water, the free CaO and free MgO contents allow for the SFS to be a potentially suitable candidate for clayey soil stabilization and improvement. In this investigation, a kaolinite clay was stabilized with 10% and 15% ladle metallurgy furnace (LMF) slag fines by weight. This experimental study also included testing of the SFS mixtures with the activator calcium chloride (CaCl2), which was hypothesized to accelerate the hydration of the dicalcium silicate phase in the SFS, but the results show that the addition of CaCl2 was not found to be effective. Relative to the unmodified clay, the unconfined compressive strength increased by 67% and 91% when 10% and 15% LMF slag were utilized, respectively. Likewise, the dynamic modulus increased by 212% and 221% by adding 10% and 15% LMF slag, respectively. Specifically, the LMF slag fines are posited to primarily contribute to a mechanical rather than chemical stabilization mechanism. Overall, these findings suggest the effective utilization of SFS as a soil stabilization admixture to overcome problems associated with dispersive soils, but further research is required. [ABSTRACT FROM AUTHOR]

Published

2020

18. Geomechanical behaviour of a soft soil stabilised with alkali-activated blast-furnace slags.

Author

Corrêa-Silva, Manuela, Miranda, Tiago, Rouainia, Mohamed, Araújo, Nuno, Glendinning, Stephanie, and Cristelo, Nuno

Subjects

*SODIC soils, *CLAY soils, *SOILS, *SOIL stabilization, *SLAG, *SOIL pollution

Abstract

The use of industrial by-products in the context of soil stabilisation has recently been explored as a mean to substitute the massive use of ordinary Portland cement (OPC), whose production has severe environmental impacts. Therefore, the purpose of the present investigation was to assess the geomechanical behaviour of a soft soil stabilised with a sustainable alkaline binder incorporating ground granulated blastfurnaces slags (GGBS), a residue from the iron industry, activated with NaOH at short (28 days) – and long (90 days) term. The mechanical characterisation included the performance of oedometer and triaxial testing, where the impact of both, initial mean effective stress (p' 0) and overconsolidation ratio (OCR) effects, was analysed on the stress-strain and volumetric strain curves, stiffness degradation and, triaxial failure surfaces of the specimens. Also, SEM-EDS, XRD and leachate analyses were also carried out at both curing ages. The mechanical results showed a significant increase of the shear strength and stiffness, and a stress-strain behaviour typical of artificially cemented soils with OPC. The detection of Si, Ca and Al suggests the formation of C-A-S-H, which explain the more pronounced development of strength and stiffness up to 28 days. No risk of soil contamination was detected due to the addition of activated GGBS to the soil. • Alkali-activated blast-furnaces slags were applied to stabilise a sandy clay soil. • Geomechanical behaviour was assessed by oedometer and triaxial tests. • Binding phases were analysed through SEM-EDS and XRD analyses. • Stabilised soil exhibited a behaviour reminiscent of cement-clay mixtures. • There is no risk of soil contamination when adding the alkaline binder to the soil. [ABSTRACT FROM AUTHOR]

Published

2020