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Nonlinear creep of concrete: Stress-activated stick–slip transition of viscous interfaces and microcracking-induced damage

Rodrigo Díaz Flores, Christian Hellmich, Bernhard Pichler

2025Cement and Concrete Research13 citationsDOIOpen Access PDF

Abstract

With the aim to identify the mechanisms governing nonlinear basic creep of concrete under uniaxial compression, a micromechanics model is presented. Extending the affinity concept for nonlinear creep, it describes that every microcrack incrementally increases the damage of concrete, leading to a step-wise increase of its compliance. Experimental data are taken from the literature. Strain and acoustic emission measurements from a multi-stage creep test are used to develop the model. This includes identification of microcrack evolution laws for both short-term load application and sustained loading. Strain measurements from four single-stage creep tests are used for model validation. It is concluded that nonlinear creep of concrete is governed by two mechanisms: (i) stress-induced stick–slip transition of viscous interfaces at the nanostructure of cement paste , which is phenomenologically accounted for by the affinity concept, and (ii) microcracking-induced damage, which is of major importance once the stress exceeds some 70% of the strength .

Topics & Concepts

Materials scienceCreepComposite materialSlip (aerodynamics)Stress (linguistics)Nonlinear systemThermodynamicsPhysicsPhilosophyQuantum mechanicsLinguisticsConcrete Properties and BehaviorInnovative concrete reinforcement materialsConcrete and Cement Materials Research