Paste Rheology and Surface Charge of Calcined Kaolinite

TL;DR

This study investigates how electrostatic interactions influence the rheology of calcined kaolinite pastes, revealing that pH and salt type significantly affect paste stiffening through surface charge variations.

Contribution

It combines rheometry, surface charge analysis, and Monte-Carlo simulations to elucidate the electrostatic mechanisms affecting calcined kaolinite paste rheology.

Findings

Paste stiffening depends on pH, salt concentration, and type.

Calcined kaolinite bears a strong negative charge at relevant conditions.

Monte-Carlo simulations qualitatively explain the rheological behavior.

Abstract

Partial substitution of the clinker in the cement by a supplementary cementitious material (SCM) is one of the main solutions to reduce the carbon footprint. Calcined kaolinite is a good candidate due to its availability and relatively high reactivity compared to other SCMs. The main issue with these calcined clay types of cements is the high-water demand at low clinker factors, a problem which remains not well understood. In this proceeding, we will show the role played by electrostatic interactions in the paste stiffening using as a model system pure calcined kaolinite paste prepared at various pH as well as salt types and concentrations. The study combines dynamic rheometry measurements in strain-sweep modes, surface charge characterization using potentiometric titration and electrophoretic measurements as well as calculations of inter-particle interactions using Monte-Carlo (MC) simulations in the framework of the primitive model. The calcined kaolinite is found to possess a negative permanent charge, presumably due to the Si(IV)/Al(III) substitution, and a titratable charge (as due to ionization of silanol and aluminol surface groups) with a point of zero proton charge at pH 4.65. In conditions relevant for cement paste, the calcined clay bear a strong negative charge ~ 300 mC/m2. The rheological measurements reveal that the paste stiffening is highly dependent on the pH, salt concentration and type as expected for systems controlled by electrostatic interactions. The stiffness increases with the salt concentration at natural pH and is the largest in solutions buffered with Ca(OH)2, that is at high Ca2+ concentrations and pH where the negative charge of the calcined clay is the strongest. The MC simulations of the inter-particle interactions are found to qualitatively explain the observed variation in the paste stiffness.