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MIGRATE

Cosserat phase field modelling and simulation of viscoplasticity induced grain boundary migration and recrystallisation in metallic polycrystals

Total Cost €

EC-Contrib. €

Partnership

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Outcomes and
results

MIGRATE project word cloud

Explore the words cloud of the MIGRATE project. It provides you a very rough idea of what is the project "MIGRATE" about.

couple stored simulations curvature orientation microstructure driving successively physical simulation grain boundary simulate finite experimental loads predicting copper paradigm mechanical offers mechanisms coalescence energies motion energy thermomechanical elastoplastic missing prior subsequent strain final constitutive gradient recrystallisation recovery primary plasticity dynamic metallic initial lattice viscoplasticity link elementary cosserat crystal optimisation force phenomena model undergoing components rotation deformation alloys possesses computed continuum evolution serves equation separately models reconciling hardening aluminium ways description morphology viscoplastic maps macroscopic aggregates polycrystals theory polycrystalline

Project "MIGRATE" data sheet

The following table provides information about the project.

Coordinator	ECOLE NATIONALE SUPERIEURE DES MINES DE PARIS Organization address address: BOULEVARD SAINT MICHEL 60 city: PARIS postcode: 75272 website: n.a. contact info title: n.a. name: n.a. surname: n.a. function: n.a. email: n.a. telephone: n.a. fax: n.a.
Coordinator Country	France [FR]
Project website	https://migrateproject.wordpress.com/
Total cost	173˙076 €
EC max contribution	173˙076 € (100%)
Programme	1. H2020-EU.1.3.2. (Nurturing excellence by means of cross-border and cross-sector mobility)
Code Call	H2020-MSCA-IF-2015
Funding Scheme	MSCA-IF-EF-ST
Starting year	2016
Duration (year-month-day)	from 2016-11-01 to 2018-10-31

Partnership

Take a look of project's partnership.

#	participants	country	role	EC contrib. [€]
1	ECOLE NATIONALE SUPERIEURE DES MINES DE PARIS ECOLE NATIONALE SUPERIEURE DES MINES DE PARIS Organization address address: BOULEVARD SAINT MICHEL 60 city: PARIS postcode: 75272 website: n.a. contact info title: n.a. name: n.a. surname: n.a. function: n.a. email: n.a. telephone: n.a. fax: n.a.	FR (PARIS)	coordinator	173˙076.00

Map

Project objective

The microstructure evolution of metallic alloys undergoing thermomechanical loads involves strain hardening, dynamic recovery, recrystallisation and grain growth. Predicting such phenomena is crucial for the control and optimisation of the mechanical properties of final components. Phase field approaches are used to simulate the change in grain morphology, growth and coalescence induced by grain boundary and stored energies due to prior viscoplastic deformation. On the other hand, continuum crystal viscoplasticity theory is well-established for finite element simulations of the deformation of polycrystalline aggregates. Currently, phase field and crystal plasticity models are used separately or successively: the field of stored elastoplastic energy computed from the crystal plasticity model serves as the initial energy distribution in the phase field simulation of subsequent grain morphology evolution. The objective of the project is to strongly couple both approaches so as to simulate dynamic grain morphology evolution during deformation processes. Each theory, i.e. the phase field model and the continuum crystal plasticity approach, possesses an evolution equation for the crystal lattice orientation. An essential driving force for lattice rotation evolution is the orientation gradient, the lattice curvature, which is the primary constitutive variable of the Cosserat continuum theory. The Cosserat theory offers a unique way of reconciling both approaches. The results of finite element simulations based on this new theory will be compared to experimental results, namely lattice orientation maps and strain field measurements, available for aluminium and copper polycrystals. The proposed model is the missing link between the physical description of grain boundary motion and macroscopic recrystallisation models. Such a paradigm has not yet been proposed and will open new ways for the understanding of elementary recrystallisation mechanisms in polycrystals.

Publications

List of publications.
year	authors and title	journal	last update
2018	Anna Ask, Samuel Forest, Benoit Appolaire, Kais Ammar A Cosseratâ€“phase-field theory of crystal plasticity and grain boundary migration at finite deformation published pages: , ISSN: 0935-1175, DOI: 10.1007/s00161-018-0727-6	Continuum Mechanics and Thermodynamics	2019-10-08
2018	Anna Ask, Samuel Forest, Benoit Appolaire, Kais Ammar, Oguz Umut Salman A Cosserat crystal plasticity and phase field theory for grain boundary migration published pages: 167-194, ISSN: 0022-5096, DOI: 10.1016/j.jmps.2018.03.006	Journal of the Mechanics and Physics of Solids 115	2019-06-13

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