Department of Mechanics: Seminar: Abstract Forest

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Samuel Forest, Matthieu Mazière, Henri Proudhon, Ozgur Aslan (MINES ParisTech CNRS, Evry, France)

The micromorphic approach to gradient plasticity and damage

A general constitutive framework is presented that encompasses a large variety of available generalized continuum theories designed for introducing material length scales into the mechanical modelling of structures and materials [1]. In particular, it reconciles so-called micromorphic and gradient theories developed in the last fifty years and applied to the plasticity and fracture of materials. The regularization operators of such models with respect to localization phenomena are derived within the finite deformation framework [2]. The approach is illustrated in the case of the propagation of Lüders bands in C-Mn steels under tensile [3,4] and shear loading [5]. The method is then applied to the plasticity and fracture of single crystalline materials [6]. Finite deformation crystal plasticity theory is enhanced to incorporate the initiation and propagation of damage with respect to crystallographic planes. The model is applicable to quasi-brittle single crystal undergoing cleavage fracture but also to ductile single crystals for which plasticity is a precursor of fracture. The approach is illustrated by means of finite element simulations of the initiation, propagation and bifurcation / branching of cracks in single crystal nickel base superalloys under cycling loading. Comparison with results from in situ microtomographic experiments at the European Synchrotron Facility are provided [7].

References:

  1. S. Forest, Micromorphic approach for gradient elasticity, viscoplasticity and damage, ASCE Journal of Engineering Mechanics, vol. 135, pp. 117-131, 2009.
  2. S. Forest, Nonlinear regularization operators as derived from the micromorphic approach to gradient elasticity, viscoplasticity and damage Proc. R. Soc. A, vol. 472, pp. 20150755, 2016.
  3. A. Marais, M. Mazière, S. Forest, A. Parrot and P. Le Delliou, Identification of a strain-aging model accounting for Lüders behavior in a C-Mn steel, Philosophical Magazine, vol. 28-30, pp. 3589-3617, 2012.
  4. M. Mazière and S. Forest, Strain gradient plasticity modeling and finite element simulation of Lüders band formation and propagation, Continuum Mechanics and Thermodynamics, vol. 27, pp. 83-104, 2015.
  5. M. Mazière, C. Luis, A. Marais, S. Forest and M. Gaspérini, Experimental and numerical analysis of the Lüders phenomenon in simple shear, International Journal of Solids and Structures, vol. 106-107, pp. 305-314, 2017.
  6. O. Aslan, N.M. Cordero, A. Gaubert, S. Forest, Micromorphic approach to single crystal plasticity and damage , International Journal of Engineering Science, vol. 49, pp. 1311-1325, 2011.
  7. H. Proudhon, J. Li, W. Ludwig, A. Roos and S. Forest, Simulation of short fatigue crack propagation in a 3D experimental microstructure , Advanced Engineering Materials, 1600721, 2017.
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