Direct numerical simulations of intrusive density- and particle-driven gravity currents

Francisco, Ezequiel Pelisoli; Espath, Luis; Laizet, Sylvain; Silvestrini, Jorge Hugo; Calo, Victor M.

doi:10.1063/5.0087595

Physics of Fluids

2022

DOI: 10.1063/5.0087595

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Direct numerical simulations of intrusive density- and particle-driven gravity currents

Ezequiel Pelisoli Francisco¹,

Luis Espath

Sylvain Laizet

et al.

Abstract: In the present study, mesopycnal flows are investigated using direct numerical simulations. In particular, intrusive density- and particle-driven gravity currents in the lock exchange setup are simulated with the high-order finite-difference framework Xcompact3d. To account for the settling velocity of particles, a customized Fick's law for the particle-solution species is used with an additional term incorporating a constant settling velocity proportional to the concentration of particles. A general energy bu… Show more

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Cited by 2 publications

References 33 publications

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Propagation, mixing, and turbulence characteristics of saline and turbidity currents over rough and permeable/impermeable beds

Dongrui

Lin

et al. 2022

Physics of Fluids

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A series of constant-flux saline and turbidity current experiments were carried out, focusing on the coupling impact of bed roughness and permeability on current propagation, mixing, and turbulence characteristics. The distinct current propagation phases on RI (rough and impermeable) and RP (rough and permeable) beds are identified respectively. Experimental results revealed that intermittently undulating bed surface breaks the strict no-slip boundary, thereby increasing local current velocity near the bed, while its roughness reduces the current peak profile velocity. Interbed pores of rough bed induce vertical fluid exchange, which synchronously decrease the current velocity, and causes the density profile no longer follow a monotonous variation trend along with water depth. The larger bed surface roughness or the interbed porosity leads to the smaller upper TKE (Turbulent Kinetic Energy) peak. On the other hand, the lower TKE peak is inversely proportional to the bed surface roughness of the RI beds but proportional to the porosity of the RP bed. Rough bed surface intensifies the asymmetry of the mean velocity distribution around peak velocity, resulting in a transfer barrier of turbulent momentum triggered by the interbed pores. For the RP bed, the cross-correlation function based on two-point statistics captures the spikes associated with pore-scale eddies locally, while on the RI condition the function only obtains the time scale characterizing the largest eddies of the current. Sediment deposition makes the turbidity current easier to separate from the RP and RI bed than the saline type, as a consequence of increasing the current height.

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Propagation, mixing, and turbulence characteristics of saline and turbidity currents over rough and permeable/impermeable beds

Dongrui

Lin

et al. 2022

Physics of Fluids

View full text Add to dashboard Cite

show abstract

Coherent structures, turbulence intermittency, and anisotropy of gravity currents propagating on a rough and porous bed

et al. 2023

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This study experimentally investigated the impacts of rough and porous (RP) bed and sedimentation processes on the coherent structures, turbulence intermittency, and anisotropy of saline and turbidity currents. Results reveal that the local current concentration responds immediately (saline current) or languidly (turbidity current) to turbulence bursting events. Inside the dense current, the turbulent momentum fluxes in streamwise and vertical directions transfer downstream and downward, which favor the sweep events. Inside the ambient water, the turbulent momentum fluxes in streamwise and vertical directions transfer upstream and upward, contributing to the formation of ejection events. At the current-ambient water interface, the turbulent momentum fluxes in streamwise and vertical directions do not tend to transfer in particular directions resulting in almost equal quantities of sweep and ejection events. The Gram-Charlier series expansion is strictly applicable to probability density functions (PDFs) of the sweep and ejection events but not suitable ideally for PDFs of the outward and inward interaction events. The primary anisotropy invariant map (AIM) of gravity currents starts from the two-component plain strain limit (near the bed). It is followed by the three-dimensional isotropy (inside the dense current and ambient water) and the axisymmetric contraction limit (current-ambient water interface). Finally, it ends in two-dimensional isotropy (near the free surface). This AIM is sensitive to the RP boundary and the sedimentation processes. Along the streamwise direction, the RP boundary causes alternations between the anisotropic and isotropic turbulence, but the arranged pattern of the rough units determines the period of this alternation.

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Direct numerical simulations of intrusive density- and particle-driven gravity currents

Cited by 2 publications

References 33 publications

Propagation, mixing, and turbulence characteristics of saline and turbidity currents over rough and permeable/impermeable beds

Propagation, mixing, and turbulence characteristics of saline and turbidity currents over rough and permeable/impermeable beds

Coherent structures, turbulence intermittency, and anisotropy of gravity currents propagating on a rough and porous bed

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