2019
DOI: 10.1029/2019jc015332
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Properties of the Body of a Turbidity Current at Near‐Normal Conditions: 1. Effect of Bed Slope

Abstract: We study the body of turbidity currents in normal flow conditions by means of highly resolved direct numerical simulations of a homogeneous model. We focus on turbidity currents where the net amount of sediment is held fixed. We consider the sediment to be fine enough that their settling effect is neglected, and in the companion work we consider the effect of settling velocity. We consider five different shear Richardson numbers from 5 to 80. Under normal condition, basal drag and entrainment at the interface … Show more

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Cited by 13 publications
(30 citation statements)
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References 57 publications
(173 reference statements)
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“…To reduce the computational time, grid clustering was used in x-direction; a width of 2 mm was used for the cells in the first 1.5 m, while the width of the remaining cells was gradually increased with a growth rate of 1.04 with an upper limit of 5 cm. The cell dimensions in the y and z directions were kept constant with a value of 2 mm and 0.5 mm, respectively (leading to maximum ∆z + = 15 for the first velocity point located at 1 2 ∆z). The average computational time of the runs presented in this study was about 4 days.…”
Section: Computational Gridmentioning
confidence: 99%
See 1 more Smart Citation
“…To reduce the computational time, grid clustering was used in x-direction; a width of 2 mm was used for the cells in the first 1.5 m, while the width of the remaining cells was gradually increased with a growth rate of 1.04 with an upper limit of 5 cm. The cell dimensions in the y and z directions were kept constant with a value of 2 mm and 0.5 mm, respectively (leading to maximum ∆z + = 15 for the first velocity point located at 1 2 ∆z). The average computational time of the runs presented in this study was about 4 days.…”
Section: Computational Gridmentioning
confidence: 99%
“…Turbidity currents are buoyancy-driven underflows generated by the action of gravity on the density difference between a fluid-sediment mixture and the ambient fluid. The excess hydrostatic pressure within the turbidity current drives the current downstream while complicated interactions with the surrounding environment take place; it interacts with the ambient fluid at the upper boundary and with the bed at the lower boundary, producing turbulence at both boundaries [1]. Turbidity currents are vital agents of sediment transport that deliver sediment from the river mouths to deeper waters [2].…”
Section: Introductionmentioning
confidence: 99%
“…As in the companion work (Salinas et al, 2019), we perform the simulations in two stages. In the first stage, we perform a simulation of a turbidity current with a roof (denoted as "TCR"-see Cantero et al, 2009) over a bed inclined at an angle .…”
Section: Mathematical and Numerical Setupmentioning
confidence: 99%
“…In the second-stage simulation the top boundary condition is enforced atz = 12 (see Figure 1b in Salinas et al, 2019), while the top of the turbidity current, which is the interface between the current and the ambient fluid above, is allowed to evolve naturally without any imposed boundary conditions. In the sections that follow, an overbar (·) denotes mean value obtained by averaging over a horizontal plane (x −̃) and over five realizations.…”
Section: Mathematical and Numerical Setupmentioning
confidence: 99%
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