On the Justification of Viscoelastic Elliptic Membrane Shell Equations

We consider a family of linearly viscoelastic shells with thickness (2varepsilon), clamped along their entire lateral face, all having the same middle surface (S=boldsymbol{theta}(bar{omega})subset mathbb{R}^{3}), where (omegasubsetmathbb{R}^{2}) is a bounded and connected open set with a Lipschitz-continuous boundary (gamma). We make an essential geometrical assumption on the middle surface (S), which is satisfied if (gamma) and (boldsymbol{theta}) are smooth enough and (S) is uniformly elliptic. We show that, if the applied body force density is (O(1)) with respect to (varepsilon) and surface tractions density is (O(varepsilon)), the solution of the scaled variational problem in curvilinear coordinates, (boldsymbol{u}( varepsilon)), defined over the fixed domain (varOmega=omegatimes (-1,1)) for each (tin[0,T]), converges to a limit (boldsymbol{u}) with (u_{alpha}(varepsilon)rightarrow u_{alpha}) in (W^{1,2}(0,T,H ^{1}(varOmega))) and (u_{3}(varepsilon)rightarrow u_{3}) in (W^{1,2}(0,T,L^{2}(varOmega))) as (varepsilonto0). Moreover, we prove that this limit is independent of the transverse variable. Furthermore, the average (bar{boldsymbol{u}}= frac{1}{2}int_{-1}^{1} boldsymbol{u}dx_{3}), which belongs to the space (W^{1,2}(0,T, V_{M}( omega))), where

$$V_{M}(omega)=H^{1}_{0}(omega)times H^{1}_{0}(omega)times L ^{2}(omega), $$

satisfies what we have identified as (scaled) two-dimensional equations of a viscoelastic membrane elliptic shell, which includes a long-term memory that takes into account previous deformations. We finally provide convergence results which justify those equations.