Litcius/Paper detail

Carbon sequestration, performance optimization and environmental impact assessment of functional materials in cementitious composites

Kailun Chen, Fulin Qu, Zihui Sun, Surendra P. Shah, Wengui Li

2024Journal of CO2 Utilization12 citationsDOIOpen Access PDF

Abstract

This paper reviews the mechanisms of carbon sequestration, methods for testing carbon sequestration capacity, and the performance of functional materials, including wollastonite, titanium dioxide nanoparticles (Nano-TiO 2 ), graphene oxide (GO), biochar, and cellulose fibers (CS), as well as their performance in cement-based materials. A system boundary model has been developed to facilitate a comprehensive analysis of the environmental impact associated with preparing these materials as concretes. It is demonstrated that wollastonite reacts with atmospheric carbon dioxide (CO 2 ) to form carbonate minerals, contributing to carbon sequestration. Nano-TiO 2 and GO absorb and transform CO 2 through light-excited charge carriers to generate redox reactions and oxide functional groups on their surfaces and edges, respectively. Biochar achieves carbon sequestration through physical and chemical stability, while the carbon sequestration mechanism in cellulose fibers is related to their structural properties as plant materials. In cement-based materials, wollastonite significantly enhances mechanical properties by filling pores and bridging microcracks. Nano-TiO 2 and GO enhance mechanical properties by providing nucleation sites and template effects, among other mechanisms. An appropriate amount of biochar improves densification and strength, while cellulose fibers facilitate the cement hydration process, thus enhancing mechanical properties. Additionally, Life Cycle Assessment (LCA) analyses demonstrate that wollastonite and cellulose fibers offer sustainable environmental benefits in producing low-carbon concrete due to their low Global Warming Potential (GWP) and minimal negative impacts on the environment and human health. This review emphasizes the pivotal role of these functional construction materials in mitigating climate change. • Wollastonite is highly efficient at carbon sequestration with CO₂ to form CaCO₃. • Nano-TiO₂ facilitates carbon sequestration through photocatalytic processes. • GO’s high surface area and functional groups provide excellent carbon capture potential. • Biochar has a high surface area and porous structure, effective for carbon capture. • Cellulose fibers provide effective pathways for CO₂ adsorption through hydroxyl groups.

Topics & Concepts

Carbon sequestrationCementitiousComposite materialMaterials scienceCarbon fibersComposite numberCarbon dioxideCementChemistryOrganic chemistryConcrete and Cement Materials ResearchRecycled Aggregate Concrete PerformanceRecycling and Waste Management Techniques