Browsing by Author "Webster, Justin T."
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Item Attractors and Determining Functionals for A Flutter Model: Finite Dimensionality Out of Thin Air(2019-04-24) Webster, Justin T.We establish the effective {\em finite dimensionality} of the dynamics corresponding to a flow-plate interaction PDE model arising in aeroelasticity: a nonlinear panel, in the absence of rotational inertia, immersed in an inviscid potential flow. An intrinsic component of the analysis is the study of a plate equation with a {\it delay} term---a fundamentally non-gradient dynamics. First, we construct a compact global attractor and observe that the attractor is smooth, with finite fractal dimension in the state space. Secondly, by fattening the attractor, we obtain an exponential attractor, though with finite dimension only in an extended space. Lastly, we show that a finite set of {\em determining functionals} exists by considering the {\em completeness defect} for some practical functionals on H20(Ω) (e.g., nodes, modes, and averages). The primary tool here is the recent quasi-stability theory of Chueshov and Lasiecka. All of the main results require {\em no imposed structural damping}, as dissipative effects are contributed by the flow through the coupling. In the final section, we discuss additional results and conjectures when imposed structural damping is present.Item A Linearized Viscous, Compressible Flow-Plate Interaction with Non-dissipative CouplingAvalos, George; Geredeli, Pelin Guven; Webster, Justin T.We address semigroup well-posedness for a linear, compressible viscous fluid interacting at its boundary with an elastic plate. We derive the model by linearizing the compressible Navier-Stokes equations about an arbitrary flow state, so the fluid PDE includes an ambient flow profile U . In contrast to model in [Avalos, Geredeli, Webster, 2017], we track the effect of this term at the flow-structure interface, yielding a velocity matching condition involving the material derivative of the structure; this destroys the dissipative nature of the coupling of the dynamics. We adopt here a Lumer-Phillips approach, with a view of associating fluid-structure solutions with a C 0 -semigroup {e At } t≥0 on a chosen finite energy space of data. Given this approach, the challenge becomes establishing the maximal dissipativity of an operator A , yielding the flow-structure dynamics.Item Weak Solutions in Nonlinear Poroelasticity with Incompressible Constituents(Elsevier, 2021-08-24) Bociu, Lorena; Muha, Boris; Webster, Justin T.We consider quasi-static poroelastic systems with incompressible constituents. The nonlinear permeability is taken to be dependent on solid dilation, and physical types of boundary conditions (Dirichlet, Neumann, and mixed) for the fluid pressure are considered. Such dynamics are motivated by applications in biomechanics and, in particular, tissue perfusion. This system represents a nonlinear, implicit, degenerate evolution problem. We provide a direct fixed point strategy for proving the existence of weak solutions, which is made possible by a novel result on the uniqueness of weak solution to the associated linear system (the permeability a given function of space and time). The linear uniqueness proof is based on novel energy estimates for arbitrary weak solutions, rather than just for constructed solutions (as limits of approximants). The results of this work provide a foundation for addressing strong solutions, as well uniqueness of weak solutions for the nonlinear porous media system.