Inhomogeneities and caustics in the sedimentation of noninertial particles in incompressible flows

TL;DR

This paper analytically explores how flow geometry causes inhomogeneities and caustics in sedimented noninertial particles within incompressible flows, emphasizing the effects of stretching and projection on observed density patterns.

Contribution

It provides a geometric framework linking flow deformation to particle density inhomogeneities and caustics formation during sedimentation.

Findings

Stretching within the particle sheet leads to inhomogeneities.

Projection of deformed sheets causes density variations.

Caustics can form as an extreme inhomogeneity scenario.

Abstract

In an incompressible flow, fluid density remains invariant along fluid element trajectories. This implies that the spatial distribution of non-interacting noninertial particles in such flows cannot develop density inhomogeneities beyond those that are already introduced in the initial condition. However, in certain practical situations, density is measured or accumulated on (hyper-) surfaces of dimensionality lower than the full dimensionality of the flow in which the particles move. An example is the observation of particle distributions sedimented on the floor of the ocean. In such cases, even if the initial distribution of noninertial particles is uniform within a finite support in an incompressible flow, advection in the flow will give rise to inhomogeneities in the observed density. In this paper we analytically derive, in the framework of an initially homogeneous particle sheet sedimenting towards a bottom surface, the relationship between the geometry of the flow and the emerging distribution. From a physical point of view, we identify the two processes that generate inhomogeneities to be the stretching within the sheet, and the projection of the deformed sheet onto the target surface. We point out that an extreme form of inhomogeneity, caustics, can develop for sheets. We exemplify our geometrical results with simulations of particle advection in a simple kinematic flow, study the dependence on various parameters involved, and illustrate that the basic mechanisms work similarly if the initial (homogeneous) distribution occupies a more general region of finite extension rather than a sheet.