Utilization phosphogypsum as a construction material for road base: a case study in Vietnam

Ngo, Huong Thi Thanh; Dang, Viet Quoc; Ho, Lanh Si; Doan, Thai Xa

doi:10.1007/s41062-021-00695-7

Cited by 18 publications

(11 citation statements)

References 42 publications

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“…This surpasses the strength of traditionally stabilized inorganic PG materials at the 7-day In comparison, Meskini et al [32] utilized fly ash and lime to stabilize PG roadbed material, achieving strengths below 1 MPa at 7 days and ranging from 1-3 MPa at 30 days. In Ngo et al's study [33], the strength of the cement: PG = 10:90 mixture was less than 1 MPa at day 7 and remained less than 2 MPa at day 28. Shen et al's research [34] reported curing strengths of 2 MPa at 7 days and 8 MPa at 28 days for slag-fly ash-PG solidified material.…”

Section: Effect Of Curing Agent Dosagementioning

confidence: 87%

“…Meskini et al [32] found that the incorporation of fly ash and lime can increase the unconfined compressive strength and enhance durability of the PG composite due to the formation of ettringite as the main hydration product responsible for strength development. Ngo et al [33] demonstrated that the stabilization of a PG and fly ash mixture, along with curing using cement and lime, leads to improved mechanical properties of PG. This approach confirms the practical feasibility of employing PG as a filling material for road base construction.…”

Section: Introductionmentioning

confidence: 99%

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Study on Synergistic Effect of Xanthan Gum and Sodium Methylsiliconate on Mechanical Strength and Water Stability of Phosphogypsum Road-Based Materials

Wu,

Xu,

Chu

et al. 2023

Materials

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To address the issues of low strength, poor water stability, and hazardous substance leaching associated with using phosphogypsum (PG) as a direct road-based material, the traditional approach involves employing inorganic cementing materials to stabilize PG, effectively addressing the problems. This study innovatively utilizes the xanthan gum (XG) and sodium methylsiliconate (SM) as curing agents for PG to solve the above problems. An organic curing agent stabilized PG was prepared by dry mixing XG and PG. The unconfined compressive strength, water stability, and leaching behavior of stabilized PG were investigated, the leaching behavior was characterized by ion leaching concentration, and the mechanisms behind the strength development of stabilized PG were explored by SEM and FTIR. The experimental results indicate that the single incorporation of XG reduced the strength and water stability of stabilized PG, while the single incorporation of SM had a limited effect on strength and water stability. In addition, the dual incorporation of XG and SM significantly improved the strength and water stability of stabilized PG. At the same time, the dual incorporation of XG and SM greatly reduced the leaching of hazardous substances from stabilized PG. These results demonstrate the feasibility of using stabilized PG for road base materials.

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Section: Effect Of Curing Agent Dosagementioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Study on Synergistic Effect of Xanthan Gum and Sodium Methylsiliconate on Mechanical Strength and Water Stability of Phosphogypsum Road-Based Materials

Wu,

Xu,

Chu

et al. 2023

Materials

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“…Japan sets a good example as it reuses 100.0% of its phosphogypsum: 60.0% as gypsum materials in the building industry, 30.0% as a cement retarder, and 10.0% as materials for the medical and food industries . Although phosphogypsum has been widely used in construction, such as cement retarder, , building materials like construction plaster and plastering mortar, and road paving materials, the size of the phosphoric industry and transportation costs have limited its reuse, with a global average reuse rate below 40.0% . , Therefore, innovative and reliable utilization strategies are essential to balance use and production and to maintain a sustainable development of phosphoric industry.…”

Section: Introductionmentioning

confidence: 99%

Bioremediation of Modified Phosphogypsum to Cultivable Anthrosol via Peanut Growth

Cao,

Deng,

Hou

et al. 2024

ACS Sustainable Resour. Manage.

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Phosphogypsum stacks have become a global environmental concern due to their massive annual production. While their primary application lies in construction, the scale of utilization pales in comparison to the production volume, necessitating the exploration of expansive, innovative applications. This study pioneers a simple and efficient strategy for phosphogypsum bioremediation, transforming modified phosphogypsum into a sustainable anthrosol. The strategy involved treating fresh phosphogypsum with calcium oxide at a 100:5 mass ratio, successfully reducing fluoride ion concentrations in the leachate to below 15.0 ppm, while maintaining an ambient pH of around 7.6. Employing peanut growth as our bioremediation model, we cultivated using 100% modified phosphogypsum. The germination rate soared to 96.0%, with a 16-week seedling average height of 19.5 cm, mirroring growth metrics in natural soil. Throughout the cultivation, notable enhancements in the total organic carbon (TOC) and total nitrogen (TN) were observed in the modified phosphogypsum. A thriving microecosystem was gradually established and characterized by the proliferation of microbial species such as gammaproteobacteria, cyanobacteria, and alphaproteobacteria. These results illuminate a transformative pathway to mitigate the challenge of phosphogypsum surplus by converting it into recyclable anthrosol, setting a precedent for potential bioremediation strategies across various industrial solid industrial wastes.

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“…Some harmful gases, such as chlorine fluoride, will enter the atmosphere. After being washed by rain, the soluble impurities in phosphogypsum will dissolve in rain and enter the soil, and then enter the surface water and groundwater through the soil [15]. At present, there are some environmental problems around phosphogypsum storage yard, such as poor water quality, abnormal toxic gas content in the atmosphere, excessive heavy metals in the soil, which seriously endanger the living environment of human beings.…”

Section: Introductionmentioning

confidence: 99%

Preparation and properties of phosphogypsum based plastering mortar

Sun,

Chen

2024

IJMSTS

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In order to reduce the negative impact of phosphogypsum accumulation on the environment, this paper uses phosphogypsum, magnesium slag, potassium dihydrogen phosphate, fly ash and calcium carbide slag to prepare gypsum based plaster mortar as a cementing material, and explores the optimal ratio of the composite cementing material through orthogonal experimental design. The mechanical properties of the test block were analyzed by the flexural and compressive strength of the test block, and the slurry properties were evaluated by the initial and final setting time, stability measurement, fluidity test and water resistance test. The experimental results show that when phosphogypsum: potassium magnesium phosphate: fly ash: When titanium gypsum =50:25:20:20, the strength of the composite system can reach 2.98Mpa in 60 days, and the initial setting time is 118min and the final setting time is 223min, which meets the requirements of GB/T25181-2019 building gypsum plaster mortar that the initial and final setting time is greater than 60min and less than 480min. Its fluidity is 237mm, which meets the requirement that the fluidity of GB/T25181-2019 building gypsum plaster mortar is greater than 100mm.

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Utilization phosphogypsum as a construction material for road base: a case study in Vietnam

Cited by 18 publications

References 42 publications

Study on Synergistic Effect of Xanthan Gum and Sodium Methylsiliconate on Mechanical Strength and Water Stability of Phosphogypsum Road-Based Materials

Study on Synergistic Effect of Xanthan Gum and Sodium Methylsiliconate on Mechanical Strength and Water Stability of Phosphogypsum Road-Based Materials

Bioremediation of Modified Phosphogypsum to Cultivable Anthrosol via Peanut Growth

Preparation and properties of phosphogypsum based plastering mortar

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