Multiscale Understanding of Tricalcium Silicate Hydration Reactions

Overview

Journal Sci Rep

Specialty Science

Date 2018 Jun 6

PMID 29867195

Citations 15

Authors

Ana Cuesta

Jesus D Zea-Garcia

Diana Londono-Zuluaga

Angeles G De la Torre

Isabel Santacruz

Oriol Vallcorba

Monica Dapiaggi

Susana G Sanfelix

Miguel A G Aranda

Affiliations

Soon will be listed here.

Abstract

Tricalcium silicate, the main constituent of Portland cement, hydrates to produce crystalline calcium hydroxide and calcium-silicate-hydrates (C-S-H) nanocrystalline gel. This hydration reaction is poorly understood at the nanoscale. The understanding of atomic arrangement in nanocrystalline phases is intrinsically complicated and this challenge is exacerbated by the presence of additional crystalline phase(s). Here, we use calorimetry and synchrotron X-ray powder diffraction to quantitatively follow tricalcium silicate hydration process: i) its dissolution, ii) portlandite crystallization and iii) C-S-H gel precipitation. Chiefly, synchrotron pair distribution function (PDF) allows to identify a defective clinotobermorite, CaSiO(OH)8.5HO, as the nanocrystalline component of C-S-H. Furthermore, PDF analysis also indicates that C-S-H gel contains monolayer calcium hydroxide which is stretched as recently predicted by first principles calculations. These outcomes, plus additional laboratory characterization, yielded a multiscale picture for C-S-H nanocomposite gel which explains the observed densities and Ca/Si atomic ratios at the nano- and meso- scales.

Citing Articles

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Mix and measure II: joint high-energy laboratory powder diffraction and microtomography for cement hydration studies.

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Spectroscopic identification of Ca-bearing uranyl silicates formed in C-S-H systems.

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