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The non-stationary micromorphic approach to gradient-damage : On time and length scales, stable time increments and micromorphic damping

Sobisch, Lennart ; Kaiser, Tobias and Menzel, Andreas LU (2026) In Computer Methods in Applied Mechanics and Engineering 448.
Abstract

Explicit finite element schemes are extensively used in industrial applications characterised by elevated strain rates and complex contact interactions. A central challenge in such simulations is the achievement of mesh-independent results while accurately capturing damage localisation and evolution. Gradient-enhanced damage models provide a robust regularisation framework. However, using a micromorphic ansatz gives rise to elliptic partial differential equations which are inherently incompatible with explicit formulations. In order to address this limitation, a non-stationary extension of the micromorphic approach is in the focus of this work: The intricate interaction of time- and length-scale effects in the extended micromorphic... (More)

Explicit finite element schemes are extensively used in industrial applications characterised by elevated strain rates and complex contact interactions. A central challenge in such simulations is the achievement of mesh-independent results while accurately capturing damage localisation and evolution. Gradient-enhanced damage models provide a robust regularisation framework. However, using a micromorphic ansatz gives rise to elliptic partial differential equations which are inherently incompatible with explicit formulations. In order to address this limitation, a non-stationary extension of the micromorphic approach is in the focus of this work: The intricate interaction of time- and length-scale effects in the extended micromorphic formulation is revealed by means of dimensional analysis, and the regularisation behaviour is evaluated numerically through mesh convergence studies and analytically by using dispersion analysis. In view of explicit solution approaches, a comprehensive study on the effect of micro inertia on stable time increments is carried out, and a thermodynamically consistent damping strategy based on dissipative microforces is proposed in order to mitigate micromorphic oscillations. The applicability of the extended micromorphic approach is exemplified by a detailed study of benchmark problems involving dynamic crack propagation.

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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Dynamic formulation, Explicit time integration, Finite deformations, Gradient-enhanced damage, Micromorphic approach, Stability analysis
in
Computer Methods in Applied Mechanics and Engineering
volume
448
article number
118478
pages
18 pages
publisher
Elsevier
external identifiers
  • scopus:105019178514
ISSN
0045-7825
DOI
10.1016/j.cma.2025.118478
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2025 The Author(s)
id
bb736d11-6c06-428f-b3ed-562b1a6d0c11
date added to LUP
2026-01-20 13:49:04
date last changed
2026-01-29 11:44:08
@article{bb736d11-6c06-428f-b3ed-562b1a6d0c11,
  abstract     = {{<p>Explicit finite element schemes are extensively used in industrial applications characterised by elevated strain rates and complex contact interactions. A central challenge in such simulations is the achievement of mesh-independent results while accurately capturing damage localisation and evolution. Gradient-enhanced damage models provide a robust regularisation framework. However, using a micromorphic ansatz gives rise to elliptic partial differential equations which are inherently incompatible with explicit formulations. In order to address this limitation, a non-stationary extension of the micromorphic approach is in the focus of this work: The intricate interaction of time- and length-scale effects in the extended micromorphic formulation is revealed by means of dimensional analysis, and the regularisation behaviour is evaluated numerically through mesh convergence studies and analytically by using dispersion analysis. In view of explicit solution approaches, a comprehensive study on the effect of micro inertia on stable time increments is carried out, and a thermodynamically consistent damping strategy based on dissipative microforces is proposed in order to mitigate micromorphic oscillations. The applicability of the extended micromorphic approach is exemplified by a detailed study of benchmark problems involving dynamic crack propagation.</p>}},
  author       = {{Sobisch, Lennart and Kaiser, Tobias and Menzel, Andreas}},
  issn         = {{0045-7825}},
  keywords     = {{Dynamic formulation; Explicit time integration; Finite deformations; Gradient-enhanced damage; Micromorphic approach; Stability analysis}},
  language     = {{eng}},
  month        = {{01}},
  publisher    = {{Elsevier}},
  series       = {{Computer Methods in Applied Mechanics and Engineering}},
  title        = {{The non-stationary micromorphic approach to gradient-damage : On time and length scales, stable time increments and micromorphic damping}},
  url          = {{http://dx.doi.org/10.1016/j.cma.2025.118478}},
  doi          = {{10.1016/j.cma.2025.118478}},
  volume       = {{448}},
  year         = {{2026}},
}