Litcius/Paper detail

Wet Carbonation of Industrial Recycled Concrete Fines: Experimental Study and Reaction Kinetic Modeling

Z. Tabrizi, Chayan Carmenate Rodríguez, Elena Barbera, Wilson Ricardo Leal da Silva, Fabrizio Bezzo

2025Industrial & Engineering Chemistry Research9 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Carbon dioxide mineralization via wet carbonation of industrial Recycled Concrete Fines (RCFs) offers a promising pathway for mitigating emissions in the cement industry, necessitating reliable kinetic models for technology scale-up. This work proposes a validated diffusion-based Shrinking Core Model describing the wet carbonation kinetics of RCFs. The model, based on parabolic diffusion law, is rigorously selected and calibrated among mineralization models in wet systems. Experimental results demonstrate a maximum carbonation efficiency of 0.81, corresponding to 95 kg CO 2 uptake per tonne of RCFs, and acceptable compressive strength development when incorporating RCFs up to 10% in blended cement. Reaction rates showed a minimal temperature impact due to the offset between the CO 2 solubility and diffusion through the product layer. Compared to Recycled Cement Paste (RCP) carbonation, higher diffusion coefficients are predicted, likely caused by looser product layer. Analysis highlights the importance of particle size and the CO 2 partial pressure, providing insights for efficient scale-up.

Topics & Concepts

CarbonationCarbonatationMaterials scienceCementCompressive strengthCarbon dioxideMineralization (soil science)Chemical engineeringEnvironmental scienceDiffusionGaseous diffusionPulp and paper industryWork (physics)Waste managementProcess engineeringParticle sizeComposite materialKinetic energyCarbonizationKineticsPozzolanic reactionConcrete and Cement Materials ResearchRecycled Aggregate Concrete PerformanceCO2 Sequestration and Geologic Interactions