Perturbation of parabolic equations with time-dependent linear operators: convergence of linear processes and solutions

Abstract

In this work we consider parabolic equations of the form \[ (u)t +A(t)u = F (t,u ), \] where is a parameter in [0,0) and \A(t), \ t∈ R\ is a family of uniformly sectorial operators. As → 0+, we assume that the equation converges to \[ ut +A0(t)u = F0 (t,u). \] The time-dependence found on the linear operators A(t) implies that linear process is the central object to obtain solutions via variation of constants formula. Under suitable conditions on the family A(t) and on its convergence to A0(t) when → 0+, we obtain a Trotter-Kato type Approximation Theorem for the linear process U(t,τ) associated to A(t), estimating its convergence to the linear process U0(t,τ) associated to A0(t). Through the variation of constants formula and assuming that F converges to F0, we analyze how this linear process convergence is transferred to the solution of the semilinear equation. We illustrate the ideas in two examples. First a reaction-diffusion equation in a bounded smooth domain, obtaining convergence of the linear process and solution. As a consequence, we also obtain upper-semicontinuity of the family of pullback attractors associated to each problem. The second example is a nonautonomous strongly damped wave equation and we analyze convergence of solution as we perturb the fractional powers of the associated linear operator.