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Nanoindentation-probed Oliver-Pharr half-spaces in alkali-activated slag-fly ash pastes: Multimethod identification of microelasticity and hardness

Markus Königsberger, Luis Zelaya-Lainez, Olaf Lahayne, Bernhard Pichler, Christian Hellmich

2021Mechanics of Advanced Materials and Structures32 citationsDOI

Abstract

The mechanical interactions of C-(N-)A-S-H (Calcium-sodium-aluminum-silicate-hydrate) gel with slag and fly ash inclusions in alkali-activated materials (AAM) are quantified through image-supported grid nanoindentation. Nonuniform distributions of indent-specific indentation properties reveal that the elasticity-related domain is up to 130 times the contact indentation depth, while the hardness-related domain, in turn, is by a factor of two to three smaller. These rather large domains are consistent with the slag/fly-ash inclusions being much stiffer and harder than the surrounding C-(N-)A-S-H gel. Corresponding Hashin-Shtirkman bounds for the overall AAM stiffness consistently frame ultrasonic data characterizing this homogenized material scale. This confirms our new testing protocol.

Topics & Concepts

NanoindentationMaterials scienceFly ashIndentationComposite materialIndentation hardnessAluminiumSlag (welding)MineralogyMicrostructureChemistryConcrete and Cement Materials ResearchAdvanced ceramic materials synthesisRock Mechanics and Modeling
Nanoindentation-probed Oliver-Pharr half-spaces in alkali-activated slag-fly ash pastes: Multimethod identification of microelasticity and hardness | Litcius