Feasibility of Using Building-Related Construction and Demolition Waste-Derived Geopolymer for Subgrade Soil Stabilization

Fan Gu¹*, Jianwei Xie¹

¹ National Engineering Research Center of Highway Maintenance Technology, Changsha University of Science & Technology, Changsha, 410114

Corresponding author: fan.gu@csust.edu.cn

Abstract

In China, annual generation of building-related construction and demolition waste (brCDW) exceeds 2 billion tons, with a recycling rate of less than 40%—significantly lower than the European average. The majority of unrecycled brCDW is either landfilled or stockpiled in suburban areas, leading to severe environmental pollution and resource wastage. Therefore, developing high-value utilization strategies is crucial to improving the overall recycling rate of brCDW. To address these issues, this study developed a novel approach by synthesizing a brCDW-derived geopolymer to stabilize high liquid limit subgrade soil. Unconfined compressive strength (UCS) tests, shear strength tests, resilient modulus tests, and permanent strain tests were conducted to investigate the effects of brCDW-derived geopolymer dosage, curing time, stress state, and moisture condition on the engineering properties of stabilized soil. Mechanistic-empirical models were employed to accurately estimate the stress-dependent resilient modulus and permanent strain of geopolymer-stabilized soil at any given stress state. In addition, scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS) tests were performed to investigate the strengthening mechanism of brCDW-derived geopolymer stabilization. Finally, the sustainability of the brCDW-derived geopolymer stabilization approach was assessed in terms of material production cost, carbon dioxide emissions, and energy consumption. Test results demonstrated that increasing geopolymer dosage effectively improved the UCS, shear strength, and resilient modulus of stabilized soil while reducing permanent strain. Additions of 8% and 12% geopolymer showed significant improvement in soil strength, whereas 4% geopolymer had negligible impact. The UCS test results indicated that 8% geopolymer provided the most economical improvement in stabilized soil. Increasing brCDW-derived geopolymer dosage effectively improved the resilient modulus of stabilized soil but did not affect its stress-dependent behavior; increasing confining pressure or decreasing deviatoric shear stress still resulted in a higher resilient modulus. The resilient modulus of geopolymer-stabilized soil was sensitive to moisture condition—when moisture content increased from optimum moisture content (OMC) to 1.15 times OMC, resilient moduli reduced by approximately 20%. Increasing brCDW-derived geopolymer dosage reduced accumulated permanent strain, and a mechanistic-empirical rutting model successfully predicted permanent strain at any given stress state. High liquid limit soil stabilized by 8% geopolymer exhibited sufficient resistance to permanent deformation; however, when moisture condition reached 1.15 OMC, 8% geopolymer might not provide adequate resistance to permanent deformation. SEM results indicated that porosity of stabilized soil decreased significantly when geopolymer dosage increased to 8%. EDS results demonstrated that predominant gel types generated from geopolymer stabilization were likely Calcium-Aluminum-Silicate-Hydrate (C-A-S-H), Calcium-Silicate-Hydrate (C-S-H), and Calcium-Aluminate-Hydrate (C-A-H) gels, with a small amount of Sodium-Alumino-Silicate-Hydrate (N-A-S-H) gel also detected. Compared to traditional soil stabilizers (e.g., conventional Portland cement and quick lime), production of brCDW-derived geopolymer saved material costs by 31–36%, reduced carbon dioxide emissions by 44–55%, and decreased energy consumption by 48–49%. In general, utilization of brCDW-derived geopolymer represents a sustainable approach for soil stabilization.

Keywords: Geopolymer, Construction and demolition waste, Soil stabilization, Resilient modulus, Permanent strain