Calcined clay is gaining recognition as a viable cement substitute for producing low-carbon binders like limestone calcined clay cement (LC3). However, its impact on workability remains unclear. This study investigates the mechanisms causing rheological issues in calcined clay-based mixes. LC3 was formulated with two calcined clays of similar chemistry but differing specific surface areas. Differential Scanning Calorimetry (DSC) and Time-Domain Nuclear Magnetic Resonance (1H TD‐NMR) measured free water at varying water-to-solid ratios, while paste and mortar rheology were evaluated and modeled. Results reveal significant differences in internal specific pore volume (0.108 cm³/g vs. 0.055 cm³/g), corresponding to varying water absorption (30 % vs. 15 % of mixing water), which increased yield stress from 106 Pa to 163 Pa and superplasticizer demand from 1.2 % to 1.3 %. A model to estimate the apparent yield tress (YODEL) clarified the role of water absorption in drastically increasing the yield stress of paste.
Ferrari, L., Nagmutdinova, A., Müller, A., Mikanovic, N., Ben-Haha, M., Bortolotti, V., et al. (2025). Disclosing the mechanism behind rheological challenges in calcined clay-based cements. CONSTRUCTION AND BUILDING MATERIALS, 492, 1-12 [10.1016/j.conbuildmat.2025.142837].
Disclosing the mechanism behind rheological challenges in calcined clay-based cements
Ferrari, Lucia
Primo
;Nagmutdinova, Anastasiia;Bortolotti, Villiam;Franzoni, Elisa
2025
Abstract
Calcined clay is gaining recognition as a viable cement substitute for producing low-carbon binders like limestone calcined clay cement (LC3). However, its impact on workability remains unclear. This study investigates the mechanisms causing rheological issues in calcined clay-based mixes. LC3 was formulated with two calcined clays of similar chemistry but differing specific surface areas. Differential Scanning Calorimetry (DSC) and Time-Domain Nuclear Magnetic Resonance (1H TD‐NMR) measured free water at varying water-to-solid ratios, while paste and mortar rheology were evaluated and modeled. Results reveal significant differences in internal specific pore volume (0.108 cm³/g vs. 0.055 cm³/g), corresponding to varying water absorption (30 % vs. 15 % of mixing water), which increased yield stress from 106 Pa to 163 Pa and superplasticizer demand from 1.2 % to 1.3 %. A model to estimate the apparent yield tress (YODEL) clarified the role of water absorption in drastically increasing the yield stress of paste.| File | Dimensione | Formato | |
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