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Phase evolution and mechanical performance of an ettringite-based binder during hydrothermal aging

Hoang Nguyen, Valter Carvelli, Wolfgang Kunther, Mirja Illikainen, Päivö Kinnunen

2021Cement and Concrete Research27 citationsDOIOpen Access PDF

Abstract

Little is known about the performance of ettringite-based binders in hydrothermal conditions. This investigation aims to gain insights into the phase evolution and corresponding mechanical performance of an ettringite-based binder considering crystallization pressure caused by late-reaction products. Additionally, the role of fiber reinforcement on the strength retention of the binder was investigated. When aged at an elevated temperature under water-saturated conditions, hard-burned MgO hydrated to form brucite. The precipitation and growth of the brucite crystals led to a crystallization pressure of approximately 200 MPa calculated using thermodynamic modelling. Damage was observed after 4 months of aging with cracks in the microstructure and eventually a failure at the macro scale. Ettringite remained stable at 60 °C due to the water-saturated conditions. Polypropylene fiber delayed crack propagation and thus reduced the damage caused by crystallization pressure. The fiber improved the flexural performance of composite attaining deflection-hardening behavior regardless of aging conditions.

Topics & Concepts

EttringiteHydrothermal circulationMaterials sciencePhase (matter)Composite materialMetallurgyChemical engineeringCementPortland cementChemistryEngineeringOrganic chemistryConcrete and Cement Materials ResearchBuilding materials and conservationRecycling and utilization of industrial and municipal waste in materials production
Phase evolution and mechanical performance of an ettringite-based binder during hydrothermal aging | Litcius