Marcus Waurick scite author profile

The paper extends well-posedness results of a previously explored class of time-shift invariant evolutionary problems to the case of non-autonomous media. The Hilbert space setting developed for the time-shift invariant case can be utilized to obtain an elementary approach to non-autonomous equations. The results cover a large class of evolutionary equations, where well-known strategies like evolution families may be difficult to use or fail to work. We exemplify the approach with an application to a Kelvin-Voigt-type model for visco-elastic solids.

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A Hilbert Space Perspective on Ordinary Differential Equations with Memory Term

Kalauch

Picard

Siegmund

et al. 2014

J Dyn Diff Equat

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Nonlocal H-convergence

Waurick

2018

Calc. Var.

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We introduce the concept of nonlocal H-convergence. For this we employ the theory of abstract closed complexes of operators in Hilbert spaces. We show uniqueness of the nonlocal H-limit as well as a corresponding compactness result. Moreover, we provide a characterisation of the introduced concept, which implies that local and nonlocal H-convergence coincide for multiplication operators. We provide applications to both nonlocal and nonperiodic fully time-dependent 3D Maxwell's equations on rough domains. The material law for Maxwell's equations may also rapidly oscillate between eddy current type approximations and their hyperbolic non-approximated counter parts. Applications to models in nonlocal response theory used in quantum theory and the description of meta-materials, to fourth order elliptic problems as well as to homogenisation problems on Riemannian manifolds are provided.

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On non‐autonomous integro‐differential‐algebraic evolutionary problems

Waurick

2014

Math Methods in App Sciences

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In this article, we show that a technique for showing well‐posedness results for evolutionary equations in the sense of Picard and McGhee [Picard, McGhee, Partial Differential Equations: A unified Hilbert Space Approach, DeGruyter, Berlin, 2011] established in [Picard, Trostorff, Wehowski, Waurick, On non‐autonomous evolutionary problems. J. Evol. Equ. 13:751‐776, 2013] applies to a broader class of non‐autonomous integro‐differential‐algebraic equations. Using the concept of evolutionary mappings, we prove that the respective solution operators do not depend on certain parameters describing the underlying spaces in which the well‐posedness results are established. Copyright © 2014 John Wiley & Sons, Ltd.

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Homogenization in Fractional Elasticity

Waurick¹

2014

SIAM J. Math. Anal.

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Marcus Waurick

On non-autonomous evolutionary problems

A Hilbert Space Perspective on Ordinary Differential Equations with Memory Term

Nonlocal H-convergence

On non‐autonomous integro‐differential‐algebraic evolutionary problems

Homogenization in Fractional Elasticity

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