Factors Affecting the Strength Formation Mechanism and Water Stability of Geopolymer Stabilized Phosphogypsum in Road Construction

Wu, Yi; Zhang, Hanbin; Lin, Haikun; Wu, Xueting; Li, Heng; Liu, Yamei; Gu, Gonghui; Xu, Jin; Chen, Shengying; Tang, Haojun; He, Hualuo; Zheng, Wenkai; Xu, Fang

doi:10.3390/coatings13091652

Cited by 3 publications

(1 citation statement)

References 57 publications

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“…Through on-site CBR testing, it was found that both met the relevant requirements. Wu [20] used cementitious materials to solidify phosphogypsum to form full solid waste materials for roadbed filling. In summary, solid waste-based cementitious materials can meet performance requirements in the solidification of heavy metals and as cementitious materials for concrete, road base, and roadbed solidification, and they exhibit some superior properties compared to traditional measures, such as the solidification of heavy metal cadmium, the freeze-thaw resistance of road base materials, and sulfate corrosion resistance in concrete.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Preparation and Shrinkage Characteristics of Multi-Source Solid Waste-Based Cementitious Materials

Wu,

Li,

Wei

et al. 2023

Materials

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Cement-stabilized macadam (CEM-SM) base layers on highways are prone to early shrinkage cracking in extremely cold and arid regions, mainly caused by the large drying shrinkage of traditional cement-stabilized base materials. A multi-component solid waste cementitious material (SWCM) was designed based on the response surface method. The synergistic reaction mechanism of SWCM was analyzed using X-ray diffractometer (XRD), Fourier transform infrared spectroscopy (FT-IR) and thermogravimetric analysis (TG). A shrinkage testing system was developed to evaluate the anti-cracking characteristics of stable macadam using multiple solid waste cementitious materials (SWCM-SM), and the strength growth law and frost resistance were analyzed. The results show that the Box–Behnken response surface model was used to obtain the optimal parameter combination for SWCM, including 60% slag, 30% steel slag, and 10% desulfurization gypsum. The compressive strength and flexural strength of SWCM-SM were 24.1% and 26.7% higher than those of CEM-SM after curing 180 days. The frost resistance of SWCM-SM was basically equivalent to that of CEM-SM, and the dry shrinkage strain of SWCM-SM was reduced by 30.7% compared to CEM-SM. It can be concluded that steel slag and desulfurization gypsum stimulate the hydration reaction of slag, thereby improving the bonding strength. Compared to CEM-SM, SWCM-SM exhibits slower hydration reaction and longer hydration duration, exhibiting characteristics of low early strength and high later strength. The early microstrain of the semi-rigid base layer is mainly caused by the occurrence of early water loss shrinkage, and the water loss rate of SWCM-SM is lower than that of CEM-SM. This study concludes that SWCM has good early crack resistance performance for stabilized crushed stones.

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Section: Introductionmentioning

confidence: 99%

Investigation of Preparation and Shrinkage Characteristics of Multi-Source Solid Waste-Based Cementitious Materials

Wu,

Li,

Wei

et al. 2023

Materials

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Replacing cement with GGBS to stabilize phosphogypsum-soil mixture in road materials: A comprehensive assessment of mechanical property, water stability and environmental performance

Wu,

Xu,

et al. 2025

Construction and Building Materials

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Treatment Methods for Harmful Impurities in Phosphogypsum and Their Applications in Road Engineering: A State-of-the-Art Review

Liu,

He,

Dang

et al. 2024

Preprint

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Phosphogypsum (PG), a significant by-product of the wet phosphoric acid production process, poses environmental and utilization challenges due to its harmful impurities, including heavy metals, fluorides, and phosphates. This review aims to evaluate the stabilization/solidification (S/S) methods for these hazardous impurities to enhance PG recycling in road engineering and other applications. A comprehensive bibliometric analysis was conducted using data from the Web of Science Core Collection, covering publications from 1985 to 2024. The review assesses the types and impacts of PG impurities on composite material performance and environmental health, detailing various S/S methods and their underlying mechanisms. Key findings suggest that blending PG with inorganic cementitious materials, incorporating additives, and using PG-based geopolymers are effective strategies for S/S. Blending PG with electrolytic manganese residue (EMR) and granulated blast furnace slag (GBFS) shows significant potential in immobilizing heavy metals and reducing environmental risks. The use of polymer materials, surface modifiers, and curing agents enhances the physical encapsulation and chemical stabilization of harmful impurities. PG-based geopolymers, formed through unique hydration reactions, offer robust encapsulation and adsorption capabilities for heavy metals. Additionally, biological treatment methods and biochar adsorption present innovative approaches for PG remediation. The main S/S mechanisms include physical encapsulation, chemical precipitation, ion exchange, and adsorption. Future research should focus on optimizing these S/S techniques, exploring synergistic combinations, and developing cost-effective and scalable solutions to improve PG recycling and promote sustainability in industrial practices.

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Factors Affecting the Strength Formation Mechanism and Water Stability of Geopolymer Stabilized Phosphogypsum in Road Construction

Cited by 3 publications

References 57 publications

Investigation of Preparation and Shrinkage Characteristics of Multi-Source Solid Waste-Based Cementitious Materials

Investigation of Preparation and Shrinkage Characteristics of Multi-Source Solid Waste-Based Cementitious Materials

Replacing cement with GGBS to stabilize phosphogypsum-soil mixture in road materials: A comprehensive assessment of mechanical property, water stability and environmental performance

Treatment Methods for Harmful Impurities in Phosphogypsum and Their Applications in Road Engineering: A State-of-the-Art Review

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