Abstract
This work presents a fast Fourier transform (FFT) based method that can be used to model interface decohesion. The inability of an FFT solver to deal with sharp interfaces discards the use of conventional cohesive zones to model the interfacial mechanical behaviour within this framework. This limitation is overcome by approximating sharp interfaces (e.g. grain/phase boundaries) with an interphase. Within the interphase, the background plastic constitutive behaviour is inherited from the respective adjacent grains. The anisotropic kinematics of the decohesion process is modelled using a damage deformation gradient that is constructed by mapping the opening strains (in normal and tangential modes) to the associated projection tensors. The degradation (damage) of the interfacial opening resistances is modelled via a dimensionless nonlocal damage variable that prevents localisation of damage within the interphase. This nonlocal variable results from the solution of a gradient damage based regularisation equation within the interphase subdomain. The damage field is constrained to the interphase region by applying a relatively large penalisation on the damage gradients inside the interphase. The extent of nonlocality ensures that the damage is largely uniform in the direction perpendicular to the interphase, thus making its thickness the theoretical lengthscale for dissipation. To achieve model predictions that are objective with respect to the interphase thickness, scaling relations of the model parameters are proposed. The numerical performance is shown for a uniform opening case and then for a propagating crack. Finally, an application to an artificial polycrystal is shown.
Highlights
The industrial requirement of high strength and tough materials necessitates a clear understanding of these properties in relation to the role of the underlying microstructure
During the last two decades, the fast Fourier transform (FFT)-based spectral method has emerged as a useful tool to serve this purpose
The Fourier transform provides an easy way to calculate them, as the nonlocal differential operations become local in Fourier space
Summary
The industrial requirement of high strength and tough materials necessitates a clear understanding of these properties in relation to the role of the underlying microstructure. The modelling of crack propagation is generally done by using either the cohesive zone (CZ) technique or the continuum damage method The former requires the use of interface elements to model the displacement discontinuity across the surfaces representative of the crack faces. Motivated by the use of cohesive zones for grain boundary sliding and separation in nanocrystalline FCC metals [33], analysis on TSL parameters influencing polycrystalline interfacial crack paths [25], it is worthwhile to explore methods such that FFT solvers can be used for similar studies. Subsequent works [15,28] extended it to a finite strain setting The former applied it to model the damage initiation at lath martensite boundaries using a viscous regularisation model while the latter modelled the crystallographic cleavage using a phase field damage formulation.
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