What question did this study set out to answer?

The research aims to develop a numerical algorithm that enhances the accuracy of solving thermomicropolar fluid equations.

March 10, 2026

Analysis of a Novel Time Filter Algorithm for the Time‐Dependent Incompressible Thermomicropolar Fluid Equations

Key Points

The research aims to develop a numerical algorithm that enhances the accuracy of solving thermomicropolar fluid equations.
Developed a time filter algorithm combining first-order scheme and linear multi-step method.
Computed linear velocity and pressure before angular velocity and temperature, effectively decoupling the system.
Conducted rigorous theoretical analysis to prove stability and derive error estimates.
Achieved second-order accuracy in temporal convergence compared to first-order methods.
Numerical experiments demonstrated the efficiency and effectiveness of the proposed algorithm.

Abstract

ABSTRACT In this paper, we present an efficient numerical algorithm for solving time‐dependent thermomicropolar fluid equations. The proposed method combines a first‐order ‐scheme, based on the linear multi‐step method (LM), with a time filter (TF) (referred to as LMTF). This approach enhances the temporal convergence rate from first‐order to second‐order accuracy while preserving computational efficiency and implementation simplicity. The algorithm first computes the linear velocity and pressure, then solves for the angular velocity, and finally for temperature, effectively decoupling the entire system. We provide a rigorous theoretical analysis of the decoupled LMTF scheme, proving its stability and deriving error estimates. Numerical experiments confirm the algorithm's effectiveness.

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Analysis of a Novel Time Filter Algorithm for the Time‐Dependent Incompressible Thermomicropolar Fluid Equations

Key Points

Abstract

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