Litcius/Paper detail

Enhancing strength and CO₂ uptake in lignite-based fly ash geopolymer mortar through supercritical carbonation

Tinkara Marija Podnar, Željko Knez, Gregor Kravanja

2025The Journal of Supercritical Fluids7 citationsDOIOpen Access PDF

Abstract

This study demonstrates the potential of supercritical CO₂ curing to enhance the performance and sustainability of lignite-based fly ash geopolymer mortar offering a promising approach to reducing CO₂ emissions in the construction industry while improving material properties. The research comprehensively compared conventional curing (GEO-REF) with supercritical CO₂ curing (GEO-CO₂), revealing that GEO-CO₂ samples exhibited higher compressive and flexural strengths, achieving peak performance almost immediately after curing. Supercritical CO₂ exposure resulted in enhanced carbonation, with a depth of up to 7.6 mm and a carbonation rate of up to 67 %. XRD confirmed phase changes due to CO₂ curing, with GEO-CO₂ showing additional calcium carbonate-calcite, calcium carbonate-aragonite, and calcium silicate hydroxide compared to GEO-REF. Nitrogen adsorption/desorption studies indicated larger pore diameters but a reduced BET surface area in GEO-CO₂ samples, suggesting structural changes due to CO₂ exposure. TGA analysis revealed that supercritical CO₂ curing reduced water retention and enhanced carbonation, resulting in increased CaCO₃ content and changes in Ca(OH)₂ levels. • Supercritical CO₂ curing significantly improves mechanical properties of geopolymers. • GEO-CO₂ samples achieve peak compressive and flexural strengths post-curing. • Enhanced carbonation depth (7.6 mm) and rate (67 %) confirmed through analysis. • XRD and nitrogen adsorption reveal structural changes and phase transformations. • TGA indicates reduced water retention and increased CaCO₃ content in GEO-CO₂.

Topics & Concepts

CarbonationFly ashGeopolymerSupercritical fluidMortarMaterials scienceEnvironmental scienceComposite materialChemistryOrganic chemistryConcrete and Cement Materials ResearchCO2 Sequestration and Geologic InteractionsGrouting, Rheology, and Soil Mechanics