6533b7d2fe1ef96bd125f7ad

RESEARCH PRODUCT

On the physico-chemical evolution of low-pH and CEM I cement pastes interacting with Callovo-Oxfordian pore water under its in situ CO2 partial pressure

Mikko VoutilainenLaure ChomatF. BrunetCéline Cau-dit-coumesA. DauzeresA. DauzeresP. Le BescopPaul SardiniJussi TimonenXavier Bourbon

subject

CementMaterials scienceAqueous solutionta114Precipitation (chemistry)Microstructure (B) Carbonation (C) Cement paste (D) Durability (C) Degradation (C)MineralogyRadioactive wasteBuilding and Construction010501 environmental sciences010502 geochemistry & geophysicsMicrostructure01 natural sciencesPore water pressureChemical engineeringGeneral Materials Science[PHYS.PHYS.PHYS-CHEM-PH]Physics [physics]/Physics [physics]/Chemical Physics [physics.chem-ph]Leaching (metallurgy)Porosity0105 earth and related environmental sciences

description

International audience; Abstract Within the framework of geological repositories for radioactive waste, structural concretes must be adapted to the underground chemical conditions. CEM I cement-based materials are characterised by high pH that may produce an alkaline plume in the near-field of the repository. In order to avoid this problem, low-pH cements have been designed. This study compares the physico-chemical behaviour of a low-pH material with a CEM I cement paste, both being subjected to leaching by an aqueous solution. An original experimental setup was designed to reproduce the underground conditions using a specific CO2 regulation device. Under these conditions, the low-pH material was strongly degraded, which results in coarser porosity, whereas thickness degradation of the CEM I cement paste is limited by the precipitation of a magnesium-calcite crust over the surface, which reduces the exchange of soluble species. This paper also presents a new approach for microstructure characterisation based on high-resolution X-ray microtomography.

yearjournalcountryeditionlanguage
2014-04-01Cement and Concrete Research
https://doi.org/10.1016/j.cemconres.2014.01.010