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Publications / SAND Report

Integrated Multiphysics Modeling of Environmentally Assisted Brittle Fracture

Rimsza, Jessica R.; Jones, Reese E.; Trageser, Jeremy T.; Hogancamp, Joshua H.; Torrence, Christa E.; Mitts, Cody A.; Mitchell, Chven A.; Taha, Mahmoud R.; Raby, Patience R.; Regueiro, Richard R.; Jadaan, Dhafer J.

Brittle materials, such as cement, compose major portions of built infrastructure and are vulnerable to degradation and fracture from chemo-mechanical effects. Currently, methods of modeling infrastructure do not account for the presence of a reactive environment, such as water, on the acceleration of failure. Here, we have developed methodologies and models of concrete and cement fracture that account for varying material properties, such as strength, shrinkage, and fracture toughness due to degradation or hydration. The models have been incorporated into peridynamics, non-local continuum mechanics methodology, that can model intersecting and branching brittle fracture that occurs in multicomponent brittle materials, such as concrete. Through development of new peridynamic capabilities, decalcification of cement and differential shrinkage in clay-cement composites have been evaluated, along with exemplar problems in nuclear waste cannisters and wellbores. We have developed methods to simulate multiphase phenomena in cement and cement-composite materials for energy and infrastructure applications.