Effect of accelerated carbonation on long-term water absorption behavior of cement-based materials

Abstract

Concrete carbonation has been proven to be a potential path for reducing the carbon footprint of cement industry. However, since carbonation reaction significantly alters the chemical composition and microstructure of cement-based materials, it is necessary to carefully assess its effects on the transport properties and durability of concrete materials. The goal of this work is to clarify the effects of accelerated carbonation on both the pore structure and long-term water absorption behavior of cement-based materials using CEM II/B-M (T-LL) as the binder. Experimental results show that exposure to \(\text {CO}_{2}\) at a concentration of over 65% for 90 days leads to substantial carbonation of \(\text {Ca(OH)}_{2}\) and other calcium-bearing phases including C–S–H gels. Accelerated carbonation results in a refined pore structure of cement paste, marked by decreased porosity but increased specific surface area accessible to both \(\text {N}_{2}\) and \(\text {H}_{2}\text {O}\). The long-term capillary absorption of non-carbonated mortar observes the square root of time law in the initial stage and then markedly deviates down, which can be well captured by the modified Richards equation accounting for water sensitivity. In contrast, the long-term absorption into carbonated mortar consistently follows the square root of time law, which could be quantified using the conventional Richards equation. This suggests that after accelerated carbonation, the pore structure of cement mortar is less sensitive to water regain, potentially attributed to the changes in the nanostructure of C–S–H gels caused by carbonation. Additionally, carbonated mortar exhibits lower sorptivity and inherent permeability than non-carbonated mortar, indicating that accelerated carbonation decelerates the water transport in cement-based materials.