Translation and rotation of a spherical particle in a turbulent boundary layer
Yi Hui Tee (1), Diogo Barros (1), Ellen K. Longmire (1) ((1), University of Minnesota, USA)

TL;DR
This study investigates the complex translation and rotation behaviors of finite-sized spherical particles in turbulent boundary layers at different Reynolds numbers, revealing lift-off, sliding, and rotation phenomena influenced by flow structures.
Contribution
It provides detailed experimental observations of particle dynamics, including lift-off, rotation, and motion modes, in turbulent boundary layers at high Reynolds numbers, which were previously less understood.
Findings
Lighter spheres tend to lift off and stay suspended longer.
Spheres exhibit multiple motion modes including saltation, resuspension, and sliding.
Rotation occurs about all axes, influenced by flow structures and wake effects.
Abstract
Three-dimensional particle tracking experiments were conducted in a turbulent boundary layer with friction Reynolds number of 700 and 1300. Two finite size spheres with specific gravities of 1.003 (P1) and 1.050 (P2) and diameters of 60 and 120 wall units were released individually from rest on a smooth wall. The spheres were marked with dots all over the surface to monitor their translation and rotation via high-speed stereoscopic imaging. The spheres accelerated strongly after release over streamwise distances of one boundary layer thickness before approaching an approximate terminal velocity. Initially, sphere P1, which had Reynolds numbers of 800 and 1900, always lifts off from the wall. Similar behavior was observed occasionally for sphere P2 with initial of 1900. The spheres that lifted off reached an initial peak in height before descending towards the…
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Taxonomy
TopicsParticle Dynamics in Fluid Flows · Aeolian processes and effects · Hydrology and Sediment Transport Processes
