An anisotropic, brittle damage model for finite strains with a generic damage tensor regularization

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Abstract

This paper establishes a generic framework for the nonlocal modeling of anisotropic damage at finite strains. By the combination of two recent works, the new framework allows for the flexible incorporation of different established hyperelastic finite strain material formulations into anisotropic damage whilst ensuring mesh-independent results by employing a generic set of micromorphic gradient-extensions. First, the anisotropic damage model, generally satisfying the damage growth criterion, is investigated for the specific choice of a neo-Hookean material on a single element. Next, the model is applied with different gradient-extensions in structural simulations of an asymmetrically notched specimen to identify an efficient choice in the form of a volumetric–deviatoric regularization. Thereafter, the generic framework, which is without loss of generality here specified for a neo-Hookean material with a volumetric–deviatoric gradient-extension, successfully serves for the complex simulation of a pressure-loaded rotor blade. The codes of the material subroutines are accessible to the public at https://doi.org/10.5281/zenodo.11171630.

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APA

van der Velden, T., Reese, S., Holthusen, H., & Brepols, T. (2026). An anisotropic, brittle damage model for finite strains with a generic damage tensor regularization. International Journal of Damage Mechanics, 35(1), 119–150. https://doi.org/10.1177/10567895251329815

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