D. Breit, L. Diening, S. Schwarzacher
Published 2012-09-28, updated 2013-05-28Version 2
We consider functions $u\in L^\infty(L^2)\cap L^p(W^{1,p})$ with $1<p<\infty$ on a time space domain. Solutions to non-linear evolutionary PDE's typically belong to these spaces. Many applications require a Lipschitz approximation $u_\lambda$ of $u$ which coincides with $u$ on a large set. For problems arising in fluid mechanics one needs to work with solenoidal (divergence-free) functions. Thus, we construct a Lipschitz approximation, which is also solenoidal. As an application we revise the existence proof for non-stationary generalized Newtonian fluids in [DRW10]. Since ${\rm div} u_\lambda=0$, we are able to work in the pressure free formulation, which heavily simplifies the proof. We also provide a simplified approach to the stationary solenoidal Lipschitz truncation of [BDF12].
Journal: Annali.di.Matematica.Pura.ed.Applicata 23 (2013) 2671-2700
An abstract framework for parabolic PDEs on evolving spaces
Lipschitz approximation for general almost area minimizing currents
A weighted $L_p$-theory for parabolic PDEs with BMO coefficients on $C^1$-domains
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