Chemical model for cement-based materials: Temperature dependence of thermodynamic functions for nanocrystalline and crystalline C–S–H phases

In the context of waste confinement and, more specifically, waste from the nuclear industry, concrete is used both as a confinement and as a building material. Its exposure to high temperatures makes its geochemical behavior difficult to predict over large periods of time. The present work aims to e...

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Bibliographic Details
Published in:Cement and concrete research 2010-06, Vol.40 (6), p.851-866
Main Authors: Blanc, Ph, Bourbon, X., Lassin, A., Gaucher, E.C.
Format: Article
Language:English
Subjects:
ALKALINE EARTH METAL COMPOUNDS
Applied sciences
BUILDING MATERIALS
Buildings. Public works
CALCIUM COMPOUNDS
CALCIUM OXIDES
CALCIUM SILICATES
Calcium–silicate–hydrate (C–S–H) B
Cement concrete constituents
CEMENTS
CHALCOGENIDES
Concrete industry
CONCRETES
CONFINEMENT
Crystal structure
CRYSTALS
DIAGRAMS
DISPERSIONS
ENERGY LEVELS
Engineering Sciences
ENTHALPY
Exact sciences and technology
EXCITED STATES
FORMATION HEAT
HOMOGENEOUS MIXTURES
HYDRATES
HYDROGEN COMPOUNDS
INDUSTRY
INFORMATION
MATERIALS
MATERIALS SCIENCE
Mathematical models
METASTABLE STATES
MIXTURES
Nanocrystals
NANOSTRUCTURES
NUCLEAR INDUSTRY
OXIDES
OXYGEN COMPOUNDS
PHASE DIAGRAMS
Phases
PHYSICAL PROPERTIES
Properties and test methods
Properties of anhydrous and hydrated cement, test methods
RADIOACTIVE MATERIALS
RADIOACTIVE WASTES
REACTION HEAT
SILICATES
SILICON COMPOUNDS
SILICON OXIDES
SOLID SOLUTIONS
SOLUTIONS
SPECIFIC HEAT
Temperature A
TEMPERATURE DEPENDENCE
TEMPERATURE RANGE
TEMPERATURE RANGE 0400-1000 K
Thermodynamic calculations B
THERMODYNAMIC PROPERTIES
WASTES
WATER
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Summary:In the context of waste confinement and, more specifically, waste from the nuclear industry, concrete is used both as a confinement and as a building material. Its exposure to high temperatures makes its geochemical behavior difficult to predict over large periods of time. The present work aims to elucidate the solubility constants, as a function of temperature, for the phases of the system CaO–SiO 2–H 2O. For the nanocrystalline phases, the present work investigates the existence of compounds of fixed composition, possibly in a metastable state. The question of whether the nanocrystalline C–S–H phases correspond to a series of phases of discrete composition or a solid solution is discussed and compared to the possible influence of impurities in the solid phases. For the crystalline phases, having established that the currently available values of thermodynamic properties were not consistent, we show that their refinement leads to a better agreement with the literature data. From the refined thermodynamic properties of crystalline C–S–H, a polyhedral decomposition model is developed. It enables to estimate the enthalpy of formation and the heat capacity of nanocrystalline C–S–H phases. Finally, verification shows that such phases remain unstable compared to the crystalline phases, at room or higher temperatures. A comparison, based on reaction enthalpies derived from experimental data indicates that predicted values for nanocrystalline C–S–H are in close agreement with experimental data. By estimating the properties of okenite and truscottite with the model developed in this study, we have been able to complete the CaO–SiO 2–H 2O phase diagram with a reasonable agreement with the literature. The case of jaffeite remains open to discussion. Finally, for the hydrate C2SH,α, the model predicts a transition with hillebrandite at 159 °C, in contradiction with the hypothesis of C2SH,α metastability.
ISSN:0008-8846
1873-3948
DOI:10.1016/j.cemconres.2009.12.004