Forthcoming events in this series
Characterization of generalized gradient Young measures in $W^{1,1}$ and $BV$
Abstract
This talk first introduces generalized Young measures (or DiPerna/Majda measures) in an $L^1$-setting. This extension to classical Young measures is able to quantitatively account for both oscillation and concentration phenomena in generating sequences.
We establish several fundamental properties like compactness and representation of nonlinear integral functionals and present some examples. Then, generalized Young measures generated by $W^{1,1}$- and $BV$-gradients are more closely examined and several tools to manipulate them (including averaging and approximation) are presented.
Finally, we address the question of characterizing the set of generalized Young measures generated by gradients in the spirit of the Kinderlehrer-Pedregal Theorem.
This is joint work with Jan Kristensen.
Non-periodic Γ-convergence
Abstract
Γ-convergence is a variational convergence on functionals. The explicit characterization of the integrand of the Γ-limit of sequences of integral functionals with periodic integrands is by now well known. Here we focus on the explicit characterization of the limit energy density of a sequence of functionals with non-periodic integrands. Such characterization is achieved in terms of the Young measure associated with relevant sequences of functions. Interesting examples are considered.
About yield surfaces of phase transformation for some shape memory alloys: duality and convexity. Application to fracture.
Abstract
Multiaxial mechanical proportional loadings on shape memory alloys undergoing phase transformation permit to determine the yield curve of phase transformation initiation in the stress space. We show how to transport this yield surface in the set of effective transformation strains of producted phase M. Two numerical applications are done concerning a Cu Al Be and a Ni Ti polycrystallines shape memory alloys. A special attention is devoted to establish a convexity criterium of these surfaces.
Moreover an application to the determination of the phase transformation surface around the crack tip for SMA fracture is performed.
At last some datas are given concerning the SMA damping behavior
AUTHORS
Christian Lexcellent, Rachid Laydi, Emmanuel Foltete, Manuel collet and Frédéric Thiebaud
FEMTO-ST Département de Mécanique Appliquée Université de Franche Comte Besançon France
A kinetic formulation for Hamilton-Jacobi equations
On Monge-Ampere type equations with supplementary ellipticity
Abstract
We present a selection of recent results pertaining to Hessian
and Monge-Ampere equations, where the Hessian matrix is augmented by a
matrix valued lower order operator. Equations of this type arise in
conformal geometry, geometric optics and optimal transportation.In
particular we will discuss structure conditions, due to Ma,Wang and
myself, which imply the regularity of solutions.These conditions are a
refinement of a condition used originally by Pogorelev for general
equations of Monge-Ampere type in two variables and called strong
ellipticity by him.
Non-conforming and conforming methods for minimization problems exhibiting the Lavrentiev phenomenon
Abstract
I will begin by talking briefly about the Lavrentiev phenomenon and its implications for computations. In short, if a minimization problem exhibits a Lavrentiev gap then `naive' numerical methods cannot be used to solve it. In the past, several regularization techniques have been used to overcome this difficulty. I will briefly mention them and discuss their strengths and weaknesses.
The main part of the talk will be concerned with a class of convex problems, and I will show that for this class, relatively simple numerical methods, namely (i) the Crouzeix--Raviart FEM and (ii) the P2-FEM with under-integration, can successfully overcome the Lavrentiev gap.
Numerical analysis of a Fourier spectral method for a pattern forming gradient flow equation
Abstract
We propose and analyze a fully discrete Fourier collocation scheme to
solve numerically a nonlinear equation in 2D space derived from a
pattern forming gradient flow. We prove existence and uniqueness of the
numerical solution and show that it converges to a solution of the
initial continuous problem. We also derive some error estimates and
perform numerical experiments to illustrate the theory.
13:30
Shock Reflection-Diffraction, Transonic Flow, and Free Boundary Problems
Abstract
Finally we will discuss some recent developments in attacking the shock reflection-diffraction problems, including the existence, stability, and regularity of global regular configurations of shock reflection-diffraction by wedges. The approach includes techniques to handle free boundary problems, degenerate elliptic equations, and corner singularities, which is highly motivated by experimental, computational, and asymptotic results. Further trends and open problems in this direction will be also addressed. This talk will be mainly based on joint work with M. Feldman.
13:00
Some results on the three dimensional Navier-Stokes equations
Abstract
12:00
12:00
"Regularization under nonlinear constraints"
Abstract
10:00
" The Gamma-limit of a finite-strain Cosserat model for asymptotically thin domains versus a formal dimensional reduction."
Abstract
It is shown that the Γ-limit based on a natural scaling assumption con- sists of a membrane like energy contribution and a homogenized transverse shear energy both scaling with h, augmented by an additional curvature stiffness due to the underlying Cosserat bulk formulation, also scaling with h. No specific bending term appears in the dimensional homogenization process. The formulation exhibits an internal length scale Lc which sur- vives the homogenization process. A major technical difficulty, which we encounter in applying the Γ-convergence arguments, is to establish equi- coercivity of the sequence of functionals as the relative thickness h tends to zero. Usually, equi-coercivity follows from a local coerciveness assump- tion. While the three-dimensional problem is well-posed for the Cosserat couple modulus μc ≥ 0, equi-coercivity forces us to assume a strictly pos- itive Cosserat couple modulus μc > 0. The Γ-limit model determines the midsurface deformation m ∈ H1,2(ω;R3). For the case of zero Cosserat couple modulus μc= 0 we obtain an estimate of the Γ - lim inf and Γ - lim sup, without equi-coercivity which is then strenghtened to a Γ- convergence result for zero Cosserat couple modulus. The classical linear Reissner-Mindlin model is "almost" the linearization of the Γ-limit for μc = 0 apart from a stabilizing shear energy term.
12:00
" Spectral computations of models for martensitic phase transformations"
Abstract
We describe how to perform high resolution simulations of viscoelastic continuum mechanical models for martensitic transformations with diffuse interfaces. The computational methods described may also be of use in performing high resolution simulations of time dependent partial differential equations where solutions are sufficiently smooth.