The regularity of the coupled system between an electrical network with fractional dissipation and a plate equation with fractional inertial rotational
Abstract
In this work we study a strongly coupled system between the equation of plates with fractional rotational inertial force (-)β utt where the parameter 0 <β≤ 1 and the equation of an electrical network containing a fractional dissipation term δ(-)θ vt where the parameter 0≤ θ≤ 1, the strong coupling terms are given by the Laplacian of the displacement speed γ ut and the Laplacian electric potential field γ vt. When β = 1, we have the Kirchoff-Love plate and when β = 0, we have the Euler-Bernoulli plate recently studied in Su\'arez-Mendes (2022-Preprinter)Suarez. The contributions of this research are: We prove the semigroup S(t) associated with the system is not analytic in (θ,β)∈ [0,1]×(0,1]-\( 1,1/2)\. We also determine two Gevrey classes: s1 >12\ 1-β3-β, θ2+θ-β\ for 2≤ θ+2β and s2> 2(2+θ-β)θ when the parameters θ and β lies in the interval (0, 1) and we finish by proving that at the point (θ,β)=(1,1/2) the semigroup S(t) is analytic and with a note about the asymptotic behavior of S(t). We apply semigroup theory, the frequency domain method together with multipliers and the proper decomposition of the system components and Lions' interpolation inequality.
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