Improvement of a clayey soil with alkali activated low-calcium fly ash for transport infrastructures applications

Corrêa-Silva, Manuela; Araújo, Nuno Miguel Faria; Cristelo, Nuno; Miranda, Tiago F. S.; Gomes, António Topa; Coelho, João

doi:10.1080/14680629.2018.1473286

Cited by 43 publications

(20 citation statements)

References 23 publications

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“…The commercially available software Minitab 17 was used which, based on the number of independent variables assumed, established a total of 13 random runs. The soil/precursor range was defined based on previous experience by the research team (Corrêa- Silva et al, 2019;Cristelo et al, 2018;Miranda et al, 2017;Rios et al, 2016); while the activator/solid range was defined after the maximum and minimum CS content in the paste that presented the most adequate workability. This range was on the 'dry side' of the Proctor curve, thus below the 17% humidity threshold that produced the expansion of the paste.…”

Section: Definition Of the Aac/soil Compositionmentioning

confidence: 99%

Compressed earth blocks stabilized with glass waste and fly ash activated with a recycled alkaline cleaning solution

Rivera

Coelho

Silva

et al. 2021

Journal of Cleaner Production

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The study reported in this paper focused on the physical-mechanical properties of compacted earth blocks (CEB) stabilised with a sustainable alkali activated cement, completely produced from wastes and residues, including coal fly ash and glass waste (from the production of ophthalmic lenses) activated with an alkaline solution resulting from the aluminium industry. A common Portuguese silty clay was used as the mineral skeleton of the blocks, which were then evaluated based on the protocols of the UNE 41410 and DIN 18945-47 standards. The results evidenced the effectiveness of the alkaline cementing agent in forming a binding matrix for the soil particles, and the resulting material was used to manufacture the earth-based masonry elements. After a careful optimisation of the sustainable binder, an average compressive strength of 17.23 MPa, in unsaturated conditions, was obtained for the blocks. The newly formed soil-binder structure was very capable to withstand wetting and drying cycles, ice-thaw cycles and erosion. The microstructure of the material was further analysed, using scanning electron microscopy and energy dispersive spectroscopy. The results demonstrated the real possibility of using this type of cement as a viable alternative to traditional soil stabilisation binders used in earth construction.

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Section: Definition Of the Aac/soil Compositionmentioning

confidence: 99%

Compressed earth blocks stabilized with glass waste and fly ash activated with a recycled alkaline cleaning solution

Rivera

Coelho

Silva

et al. 2021

Journal of Cleaner Production

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“…The sudden increase in the percentage of Na indicates the possibility of geopolymer gel formation (NASH) [49]. It was proved that low calcium fly ash-based geopolymer results in N-A-S-H formation as a dominant gel, and very low and slower development of calcium silicate hydrate (C-S-H) gel [50]. The decline in the percentages of Si and Al (from point 1 to 3) was mainly a result of the geopolymer reaction with the time elapsed via dissolving alumina and silica, confirming the significant growth in strength [49].…”

Section: Microstructural Analysismentioning

confidence: 99%

Strength Development and Microstructural Behavior of Soils Stabilized with Palm Oil Fuel Ash (POFA)-Based Geopolymer

2021

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Using geopolymer in soil stabilization has gained much attention recently due to its efficiency in improving soil properties and being environmentally friendly at the same time. This research aims to investigate the effect of palm oil fuel ash (POFA)-based geopolymer on soft soil stabilization. The mechanical and microstructural performance of two types of clay soil treated with geopolymer produce from POFA material was the focus of this study. In this respect, a series of unconfined compression and direct shear tests were conducted to investigate the mechanical properties of soils treated with POFA-based geopolymer. Furthermore, the microstructural changes in the treated samples were analyzed using field emission electron microscopy (FESEM) and energy dispersive X-ray (EDX). In accordance with the results, it was indicated that the shear strength of both soils soared by increasing the dosage of POFA-based geopolymer. Geopolymer with 40% POFA of the dry weight of soils yielded the highest UCS value at both curing periods, 7 and 28 days. Furthermore, the microstructural analysis revealed material modifications (N-A-S-H gel formation) related to strength enhancement. These results suggest the potentiality of using a POFA-based geopolymer binder to stabilize soft soil.

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“…The latter reaches very significant increases after only 28 days (90 to 95% of its ultimate compressive strength), while alkaline cements based on low-calcium precursors, like the FA used in the present study, have shown significant strength gains even after 90 days [1,14]. The soil used during this research work was already submitted to previous studies that primarily focused on stabilisation with cement and lime, but also with alkaline cements based on FA, aiming at increasing its uniaxial compressive strength (UCS) [2,16]. In short, these studies found that conventional binders reached higher UCS values after 28 days, while the alkaline cements were able to produce higher UCS for longer curing periods, up to 90 days.…”

Section: Introductionmentioning

confidence: 74%

“…However, the rising and ever more acute concerns with the environment have shifted the most important paradigm in the construction industry-the Portland cement dependency-towards the need for more environmentally friendly binders. Alkaline activation is a strong example which, by allowing the introduction of industrial wastes and residues into the fabrication of such alternative binders, represents a twofold advantage, by mitigating the need for OPC and by reducing the volume of wastes that are landfilled [1][2][3][4][5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

“…From a mechanical performance perspective, the first studies focusing on the use as a soil stabiliser have demonstrated clear and significant increases in compressive strength [2,3,14] and split tensile strength [15], as well as increases in stiffness [16,17], relatively to the original soils. The effectiveness of the technique is also a function of the intrinsic properties of the soil, but especially of the quality of the precursor (unburned rate, original composition, amorphisation degree), of the type of activator (alkali concentration, hydroxide/silicate ratio) and of the activator/precursor ratio (including the total water content and the alkali/precursor ratio) [1,16,18].…”

Section: Introductionmentioning

confidence: 99%

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Unsaturated Response of Clayey Soils Stabilised with Alkaline Cements

et al. 2020

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The influence of suction on the mechanical behaviour of unsaturated chemically stabilised soils is still mostly unknown and unquantified. This is also motivated by the difficulties associated with the experimental procedure required to fully characterise the unsaturated response of the soil, including its direct influence on traditional strength tests. The present paper presents the soil water retention curves obtained for a Portuguese soil before and after being stabilised with Portland cement (OPC) and an alkali-activated cement (AAC). Saturated undrained triaxial tests were also performed for the same curing conditions (0, 28, and 90 days). Previous attempts to characterise the retention curve of soils stabilised with AAC are unknown, and the results showed that the pore volume structure is already formed after 28 days, prior to the full development of the gel matrix responsible for the strength increase between 28 and 90 days. The curve changed after stabilisation, and with each binder, as the OPC presented a higher air-entry value and a narrower suction range compared to the AAC solution. The significant differences between the curves obtained from each binder suggest the future development of a methodology to assess the quality of the AAC stabilisation.

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Improvement of a clayey soil with alkali activated low-calcium fly ash for transport infrastructures applications

Cited by 43 publications

References 23 publications

Compressed earth blocks stabilized with glass waste and fly ash activated with a recycled alkaline cleaning solution

Compressed earth blocks stabilized with glass waste and fly ash activated with a recycled alkaline cleaning solution

Strength Development and Microstructural Behavior of Soils Stabilized with Palm Oil Fuel Ash (POFA)-Based Geopolymer

Unsaturated Response of Clayey Soils Stabilised with Alkaline Cements

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