Flow dynamics and mixing processes in hydraulic jump arrays: Implications for channel-lobe transition zones

• Published in: Marine geology Vol. 381; pp. 181 - 193
• Main Authors: Dorrell, R.M., Peakall, J., Sumner, E.J., Parsons, D.R., Darby, S.E., Wynn, R.B., Özsoy, E., Tezcan, D.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.11.2016
• Subjects: Arrays; Channel-lobe transition zone; Channels; Computational fluid dynamics; Dynamics; Fluid flow; Gravity currents; Hydraulic jumps; Hydraulics; Marine; Scouring; Segregations; Stratification; MED, Black Sea; Gravity currents; Stratification; Channel-lobe transition zone; Hydraulic jumps
• ISSN: 0025-3227; 1872-6151
• DOI: 10.1016/j.margeo.2016.09.009

A detailed field investigation of a saline gravity current in the southwest Black Sea has enabled the first complete analysis of three-dimensional flow structure and dynamics of a series of linked hydraulic jumps in stratified, density-driven, flows. These field observations were collected using an acoustic Doppler current profiler mounted on an autonomous underwater vehicle, and reveal that internal mixing processes in hydraulic jumps, including flow expansion and recirculation, provide a previously unrecognised mechanism for grain-size sorting and segregation in stratified density-driven flows. Field observations suggest a newly identified type of hydraulic jump, that is a stratified low Froude number (<1.5–2) subaqueous hydraulic jump, with an enhanced ability to transport sediment downstream of the jump, in comparison to hydraulic jumps in other subaerial and submarine flows. These novel field data underpin a new process-based conceptual model of channel lobe transition zones (CLTZs) that explains the scattered offset nature of scours within such settings, the temporal variations in infill and erosion between adjacent scours, how bed shear stresses are maintained across the CLTZ, and why the locus of deposition is so far downstream of the scour zone. •First field observations of gravity current dynamics over linked hydraulic jumps.•A new conceptual model for internal hydraulic jumps in stratified gravity currents.•Stratification promotes and enhances sediment transport across hydraulic jumps.•Hydraulic jumps have large spatial effects controlling channel-lobe transition zones.