Long-time error estimate and decay of finite element method to a generalized viscoelastic flow

TL;DR

This paper provides a detailed analysis of a finite element method for a generalized viscoelastic flow model, establishing long-time error estimates and decay properties, supported by theoretical proofs and numerical simulations.

Contribution

It introduces a novel analysis framework for a generalized viscoelastic flow model with tempered memory kernel, including long-time error estimates and decay results.

Findings

Proves regularity and exponential decay of solutions

Develops a Volterra-Stokes projection for analysis

Validates the model with a benchmark flow simulation

Abstract

This work analyzes the finite element approximation to a viscoelastic flow model, which generalizes the Navier-Stokes equation and Oldroyd's model by introducing the tempered power-law memory kernel. We prove regularity and long-time exponential decay of the solutions, as well as a long-time convolution-type Gr\"onwall inequality to support numerical analysis. A Volterra-Stokes projection is developed and analyzed to facilitate the parabolic-type duality argument, leading to the long-time error estimates and exponential decay of velocity and pressure. A benchmark problem of planar four-to-one contraction flow is simulated to substantiate the generality of the proposed model in comparison with the Navier-Stokes equation and Oldroyd's model.