P. Engels scite author profile

Plastic deformation of a model glass is investigated via large scale molecular dynamics simulations. The role of microscopic fluctuations of the structure for the deformation behavior is highlighted by demonstrating that statistically independent samples prepared via an identical protocol develop qualitatively distinct deformation paths. As a quantitative measure, the spatial distribution of the particle based excess volume is monitored via Voronoi tesselation. While the fluctuations of the thus defined single-particle based excess volume do not seem to show any signature of the strain field, a non-local definition of the excess volume clearly correlates with the observed shear deformation field. The distribution of the force acting on individual particles also shows a pattern strongly similar to that of the strain. In line with other studies, these results underline the importance of both the structural heterogeneities as well as the fluctuations of the locally acting forces and stresses for plastic deformation in amorphous solids.

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Continuum simulation of the evolution of dislocation densities during nanoindentation

Engels

Hartmaier

2012

International Journal of Plasticity

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Large strain elasto-plasticity for diffuse interface models

Borukhovich

Engels

Böhlke

et al. 2014

Modelling Simul. Mater. Sci. Eng.

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Most solid-state phase transformations are accompanied by large deformations, stemming either from external load, transformation strains or plasticity. The consideration of such large deformations will affect the numerical treatment of such transformations. In this paper, we present a new scheme to embed large deformations in an explicit phase-field scheme and its implementation in the open-source framework OpenPhase. The suggested scheme combines the advantages of a spectral solver to calculate the mechanical boundary value problem in a small strain limit and an advection procedure to transport field variables over the calculation grid. Since the developed approach should be used for various sets of problems, e.g. simulations of thermodynamically driven phase transformations, the mechanic formulation is kept general. However, to ensure compatibility with phase-field methods using the concept of diffuse interface, the latter is treated with special care in the present work.

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Wall effects on spatial correlations of non-affine strain in a 3D model glass

Hassani¹,

Engels²,

Varnik³

2018

EPL

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Effects of hard planar walls with a particle scale roughness on the spatial correlations of nonaffine strain in amorphous solids are investigated via molecular dynamics simulations. When determined within layers parallel to the wall plane, normalized non-affine strain correlations are enhanced within layers closer to the wall. The amplitude of these correlations, on the other hand, is found to be suppressed by the wall. While the former is connected to the effects of a hard boundary on the continuum mechanics scale, the latter is attributed to molecular scale wall effects on the size of the region (nearest neighbor cage), explored by particles on intermediate times scales.

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P. Engels

Formulation of nonlocal damage models based on spectral methods for application to complex microstructures

Localized plastic deformation in a model metallic glass: a survey of free volume and local force distributions

Continuum simulation of the evolution of dislocation densities during nanoindentation

Large strain elasto-plasticity for diffuse interface models

Wall effects on spatial correlations of non-affine strain in a 3D model glass

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