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Main Authors: Sarem, Mina, Deresse, Nuhamin Eshetu, Verstrynge, Els, François, Stijn
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.11838
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author Sarem, Mina
Deresse, Nuhamin Eshetu
Verstrynge, Els
François, Stijn
author_facet Sarem, Mina
Deresse, Nuhamin Eshetu
Verstrynge, Els
François, Stijn
contents In this paper, we extend a micromechanics-based phase-field framework for fatigue fracture to incorporate cyclic plasticity with ratcheting. This mechanism is particularly relevant for low-cycle fatigue, where the accumulation of inelastic strains plays a critical role in the progression to final failure. An energetic formulation is proposed in which the ratcheting strain is explicitly incorporated into both the free energy and the dissipation potential. Ratcheting is modeled within a pressure-dependent, non-associative plasticity framework through the evolution of a ratcheting strain that progressively accumulates over loading cycles, capturing the characteristic inelastic strain growth of cyclic plasticity in a thermodynamically consistent manner. The plastic potential is formulated such that the deviatoric and volumetric components of ratcheting can be controlled independently. A staggered solution scheme is employed to solve for the internal variables, including the ratcheting strain. Numerical examples under monotonic and cyclic loading conditions are presented to evaluate the proposed model and to investigate the influence of ratcheting on the material response.
format Preprint
id arxiv_https___arxiv_org_abs_2511_11838
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Phase-field modeling of cyclic behavior in quasi-brittle materials: a micromechanics-based approach
Sarem, Mina
Deresse, Nuhamin Eshetu
Verstrynge, Els
François, Stijn
Applied Physics
In this paper, we extend a micromechanics-based phase-field framework for fatigue fracture to incorporate cyclic plasticity with ratcheting. This mechanism is particularly relevant for low-cycle fatigue, where the accumulation of inelastic strains plays a critical role in the progression to final failure. An energetic formulation is proposed in which the ratcheting strain is explicitly incorporated into both the free energy and the dissipation potential. Ratcheting is modeled within a pressure-dependent, non-associative plasticity framework through the evolution of a ratcheting strain that progressively accumulates over loading cycles, capturing the characteristic inelastic strain growth of cyclic plasticity in a thermodynamically consistent manner. The plastic potential is formulated such that the deviatoric and volumetric components of ratcheting can be controlled independently. A staggered solution scheme is employed to solve for the internal variables, including the ratcheting strain. Numerical examples under monotonic and cyclic loading conditions are presented to evaluate the proposed model and to investigate the influence of ratcheting on the material response.
title Phase-field modeling of cyclic behavior in quasi-brittle materials: a micromechanics-based approach
topic Applied Physics
url https://arxiv.org/abs/2511.11838