Comparing surface and deep horizontal distributions of depth-keeping particles in shallow fluid layers

Abstract

This study examines whether the dispersion of passive particles at the free surface of a generic (nonturbulent) shallow flow can reliably represent the behavior of depth-keeping particles below the surface. A shallow configuration characterize many aquatic environments, such as coastal regions and lakes, where horizontal scales far exceed vertical ones, large-scale flow structures dominate, and observations are sometimes limited to the surface. We compare surface and subsurface horizontal velocities in both direction and magnitude, identifying distinct behaviors depending on the parameter ReFδ2, where ReF is the Reynolds number based on forcing, and δ is the aspect ratio between the fluid layer depth and the horizontal forcing scale. At low ReFδ2, deep flows match the surface flow in direction throughout the layer, but not in magnitude. At high ReFδ2, the magnitude matches (outside the bottom boundary layer), but not always the direction. Despite these differences, for all ReFδ2, surface particle patterns correlate with those in the upper quarter of the fluid layer. Filamentary structures caused by horizontal flow convergence remain spatially aligned within this region. Below it, at intermediate ReFδ2, deep filaments become diffuse and eventually vanish. At high ReFδ2, filaments persist at depth, but become spatially misaligned with surface filaments. These findings suggest that in shallow environments, surface observations can quantitatively infer subsurface transport processes in the upper quarter of the fluid layer. For the deeper part, knowledge of the vertical profiles of the mean flow yields insights into the horizontal transport processes.