Numerical Analysis Of Fully Explicit Phase-Field Models For Dynamic Fracture Of Materials H/F
CEA Industrie
Canton de Gif-sur-Yvette, France
25 days ago
Role details
Contract type
Internship / Graduate position Employment type
Full-time (> 32 hours) Working hours
Regular working hours Languages
EnglishJob location
Canton de Gif-sur-Yvette, France
Tech stack
C++
Pascal (Programming Language)
Requirements
postgraduate degree
INTERN FULL_TIME
About the company
Il apporte des solutions concrètes à leurs besoins dans quatre domaines principaux : transition énergétique, transition numérique, technologies pour la médecine du futur, défense et sécurité sur un socle de recherche fondamentale. Le CEA s'engage depuis plus de 75 ans au service de la souveraineté scientifique, technologique et industrielle de la France et de l'Europe pour un présent et un avenir mieux maîtrisés et plus sûrs.
Implanté au coeur des territoires équipés de très grandes infrastructures de recherche, le CEA dispose d'un large éventail de partenaires académiques et industriels en France, en Europe et à l'international.
Les 20 000 collaboratrices et collaborateurs du CEA partagent trois valeurs fondamentales :
- La conscience des responsabilités
- La coopération
- La curiosité
Understanding material fracture is paramount in the nuclear industry to ensure the structural integrity and long-term safety of critical components. Therefore, accurately simulating the onset of cracks and their propagation is essential.
Among several approaches to simulate the fracture of materials, the phase-field approaches have gain popularity in the last years. In recent developments the phase-field approaches have been extended to situations where both the mechanical response and the crack-driving variable evolve dynamically. In such formulations, the mechanical equilibrium is governed by an hyperbolic equations, while the phase-field variable itself can also follow an hyperbolic evolution law that captures inertia or rate-dependent effects in the damage process. Explicit schemes are attractive for dynamic fracture because they naturally accommodate wave propagation and avoid the repeated solution of large nonlinear systems. Yet, they are only conditionally stable, and the admissible time step is usually estimated through CFL-type conditions derived from simplified arguments. Some of our investigations have suggested that phase field equations conditions might be very unfavorable since its associated
critical timestep can fall to zero. However, it is still unclear if breaking this condition is prohibitive, since some calculations have been performed by this way [1, 2].
The aim of this internship is to investigate these issues through a numerical study of the coupled hyperbolic system. The student will try to assess if classical stability bounds may become overly conservative or, find a way to overcome these rules if it is not.
To do so, the candidate will come on board the Manta project [3], which is the framework of the nextgen finite element software for computational mechanics at CEA, and the Laboratoire d'Etudes de DYNamique lab, which hosts some of CEA leading experts in structural dynamics for civil nuclear applications.