Pressure strain correlation modeling for turbulent flows

TL;DR

This paper reviews the modeling of pressure strain correlation in Reynolds Stress Models for turbulent flows, discussing theories, existing models, recent advances, and future challenges to improve turbulence simulation accuracy.

Contribution

It provides a comprehensive review of pressure strain correlation models, including recent developments and detailed analysis of their successes and limitations.

Findings

Established models' performance compared to experimental data

Recent advances in pressure strain correlation modeling

Identification of key challenges for future research

Abstract

Almost all investigations of turbulent flows in academia and in the industry utilize some degree of turbulence modeling. Of the available approaches to turbulence modeling Reynolds Stress Models have the highest potential to replicate complex flow phenomena. Due to its complexity and its importance in flow evolution modeling of the pressure strain correlation mechanism is generally regarded as the key challenge for Reynolds Stress Models. In the present work, the modeling of the pressure strain correlation for complex turbulent flows is reviewed. Starting from the governing equations we outline the theory behind models for both the slow and rapid pressure strain correlation. Established models for both these are introduced and their successes and shortcomings are illustrated using simulations and comparisons to experimental and numerical studies. Recent advances and developments in this context are presented. Finally, challenges and hurdles for pressure strain correlation modeling are outlined and explained in detail to guide future investigations.