| Abstract: |
| We investigate a semilinear wave equation with energy critical nonlinearity and a nonlinear damping mechanism driven by the total energy of the system. The model combines the quintic defocusing term with a time dependent dissipation of the form $E(t)u_t$, which introduces a nonstandard feedback structure coupling the dynamics and the energy functional. Weak solutions are constructed via Galerkin approximations, with the passage to the limit relying on uniform energy estimates and compactness arguments. Special attention is devoted to the critical nature of the nonlinearity, where concentration phenomena prevent purely energy-based methods from yielding refined spacetime control. This difficulty is resolved by incorporating nonhomogeneous Strichartz estimates together with smoothly truncated spectral approximations, ensuring uniform bounds at the dispersive level. Finally, we establish polynomial decay rates for the energy by adapting Nakao`s method to the present nonlinear dissipative framework. The results highlight the stabilizing effect of the energy dependent damping and its interaction with the critical wave dynamics. |
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