Forward and backward in time dispersion of fluid and inertial particles in isotropic turbulence

TL;DR

This study investigates the forward and backward in time dispersion of fluid and inertial particles in isotropic turbulence, revealing that inertial particles exhibit stronger irreversibility than fluid particles, influenced by non-local velocity dynamics.

Contribution

The paper provides a combined theoretical and numerical analysis of inertial particle dispersion, highlighting the enhanced irreversibility due to non-local effects and identifying an optimal Stokes number for maximum irreversibility.

Findings

Inertial particles show greater dispersion irreversibility than fluid particles.

Irreversibility increases as particle separation scale decreases.

An optimal Stokes number exists where irreversibility is maximized.

Abstract

In this paper we investigate both theoretically and numerically the forward in time (FIT) and backward in time (BIT) dispersion of fluid and inertial particle pairs in isotropic turbulence. Fluid particles are known to separate faster BIT than FIT in three-dimensional turbulence, and we find that inertial particles do the same. However, we find that the irreversibility in the inertial particle dispersion is in general much stronger than that for fluid particles. For example, the ratio of the BIT to FIT mean-square separation can be up to an order of magnitude larger for inertial particles than for the fluid particles. We also find that for both the inertial and fluid particles the irreversibility becomes stronger as the scale of their separation decreases. Regarding the physical mechanism for the irreversibility, we argue that whereas the irreversibility of fluid particle-pair dispersion can be understood in terms of a directional bias arising from the energy transfer process in turbulence, inertial particles experience an additional source of irreversibility arising from the non-local contribution to their velocity dynamics, a contribution which vanishes in the limit ${St\to0}$, where $St$ is the particle Stokes number. For each given initial (final, in the backward in time case) separation $\bm{r}^0$ there is an optimum value of $St$ for which the dispersion irreversibility is strongest, as such particles are optimally affected by both sources of irreversibility. We derive analytical expressions for the BIT, mean-square separation of inertial particles and compare the predictions with...