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The Evolution of Flow and Mass Transport in 3D Confined Cavities

Flow in channels and ducts with adjoining cavities are common in natural and engineered systems. Here we report numerical and experimental results of 3D confined cavity flow, identifying critical conditions in the recirculating flow formation and mass transport over a range of channel flow properties ($0.1\leq Re \leq 300$) and cavity aspect ratio ($0.1 \leq H/X_{s} \leq1$). In contrast to 2D systems, a mass flux boundary is not formed in 3D confined cavity-channel flow. Streamlines directly enter a recirculating vortex in the cavity and exit to the main channel leading to an exponential increase in the cavity mass flux when the recirculating vortex fills the cavity volume. These findings extend our understanding of flow entry and exit in cavities and suggest conditions where convective mass transport into and out of cavities would be amplified and vortex particle capture reduced.

preprint2021arXivOpen access
Reem KhojahDarren LoFiona TangDino Di Carlo
Biological Physicsphysics.flu-dyn
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Reem KhojahDarren LoFiona TangDino Di Carlo

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