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Mesoscale model and X-ray computed micro-tomographic imaging of damage progression in ultra-high-performance concrete

Michael Homel, Jaisree Iyer, Shabnam J. Semnani, Eric B. Herbold

2022Cement and Concrete Research49 citationsDOIOpen Access PDF

Abstract

Predicting the mechanical performance of concrete from composition and processing remains a grand challenge. Our work focuses on predicting damage evolution in ultrahigh-performance concrete (UHPC), where analysis is challenging due to a lack of separation in the length scales of heterogeneity and a limited availability of data to describe the strength and failure of individual phases. Cement-hydration modeling informs segmentation of CT images from mechanical tests, providing a highly resolved 3-D representation of microstructure and damage evolution. Mesoscale simulations of damage in UHPC reveal how the relative strength of cement phases affects patterns of intra- and inter-granular fracture. We find that the nano-indentation hardness of individual phases is not necessarily a predictor of the relative shear strength needed to match experimentally observed fracture patterns. The mesoscale model predicts complicated material responses as emergent phenomena from relatively simple models of individual phases - a path towards forward modeling UHPC constitutive response.

Topics & Concepts

Mesoscale meteorologyMaterials scienceFracture (geology)Representation (politics)MicrostructureIndentationShear (geology)Structural engineeringComposite materialGeologyEngineeringLawClimatologyPoliticsPolitical scienceConcrete and Cement Materials ResearchRock Mechanics and ModelingInnovative concrete reinforcement materials
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