Periodic Reporting for period 1 - FatiguEvoPro (Quasistatic evolution problems for material failure due to fatigue)
Période du rapport: 2019-12-01 au 2021-11-30
Fatigue is responsible for most of unforeseen mechanical failures. These affect people and society at all levels, encompassing all possible structures: everyday-life items, human body prostheses, buildings, bridges, ground vehicles, ships, aeroplanes, oil platforms, etc. In most dramatic situations, the consequences of fatigue failure can be catastrophic, causing tremendous financial losses, serious injuries, and deaths.
Investigating fatigue phenomena is a crucial aspect in the Engineering community, however so far scarcely investigated by the Mathematics community. This results in the lack of proofs of consistency and well-posedness for variational models of material fatigue.
The overall aim of the project has been to prove the existence of evolutions for mechanical models of material fatigue.
This has been pursued by examining fatigue in the different contexts of damage, plasticity, and cohesive fracture.
More precisely, the following objectives have been tackled:
– Objective 1: Proving an existence theorem for quasistatic evolutions in regimes of high-cylcle fatigue;
– Objective 2: Proving a well-posedness theorem for models involving the coupling between damage and plasticity;
– Objective 3: Proving the existence of quasistatic evolutions for cohesive fracture due to fatigue.
For Objective 1, we considered a gradient damage model featuring a term depending on the cumulated elastic strain that appears in the dissipation of damage. As a consequence of this term, the energy dissipated to produce a damage increment becomes lower in the regions where the material has experienced oscillations of the elastic strain. We proved existence of evolutions via a vanishing viscosity approach.
For Objective 2, we considered a model for linearised elasto-plasticity coupled with damage and we proved the lower semicontinuity of the plastic potential term in the energy only requiring only H1 regularity of the damage.
For Objective 3, we studied a cohesive fracture model with fatigue in the one-dimensional setting, where fracture concentrates on points.
Finally, we additionally studied discrete-to-continuum limits of atomistic systems, with applications to dislocation theory.
The results have been disseminated with seminars and talks in conferences.
The results obtained open a new line of research in the variational modelling of Fracture Mechanics and create many future perspectives, like the following problems: i) brittle fracture due to plastic fatigue; ii) brittle fracture as sharp-interface limit of damage in the context of fatigue phenomena; iii) discrete-to-continuum motivation of fatigue, etc.
Some of the techniques developed have great potential for applications in different contexts, as shown by the applications of tools from Geometric Measure Theory to discrete-to-continuum limits of atomistic systems.
The outcome of the project will also improve the perception among the general public of the work done by mathematicians. Indeed, the common thought is that research in Mathematics only deals with abstract theories and that the produced results are only exploitable by mathematicians themselves. Instead, it concerns also real problem like fatigue failure.