Velocity and concentration profiles of saline and turbidity currents flowing in a straight channel under quasi-uniform conditions

Stagnaro, Mattia; Pittaluga, M. Bolla

doi:10.5194/esurf-2-167-2014

Cited by 23 publications

(16 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Variations are to be expected with differences in basal materials, laboratory conditions and the difficulty in defining a current's height. A dependence of h max on both the flow's Richardson number (Sequeiros et al, ) and Reynolds number (Stagnaro & Pittaluga, ) has also been observed. For the partially confined flows analyzed here, h max remains nearly constant for all the laboratory‐scale flows at a height equal to half the channel depth, regardless of flow height or Richardson number.…”

Section: Discussionmentioning

confidence: 87%

“…However, this approach has limitations for erosional or bypassing flows as it does not take into account Reynolds‐dependent turbulent effects in the lower boundary (Imran et al, ). Also, high‐velocity maximum heights were not replicated in the simulations of Kneller et al (), despite the stably stratified layer, nor in further experiments of subcritical flows which found limited dependence on Richardson number (Stagnaro & Pittaluga, ).…”

Section: Introductionmentioning

confidence: 90%

See 1 more Smart Citation

The Structure and Entrainment Characteristics of Partially Confined Gravity Currents

2019

View full text Add to dashboard Cite

Seafloor channels are the main conduit for turbidity currents transporting sediment to the deep ocean, and they can extend for thousands of kilometers along the ocean floor. Although it is common for channel‐traversing turbidity currents to spill onto levees and other out‐of‐channel areas, the associated flow development and channel‐current interaction remain poorly understood; much of our knowledge of turbidity current dynamics comes from studies of fully confined scenarios. Here we investigate the role that partial lateral confinement may play in affecting turbidity current dynamics. We report on laboratory experiments of partially confined, dilute saline flows of variable flux rate traversing fixed, straight channels with cross‐sectional profiles representative of morphologies found in the field. Complementary numerical experiments, validated against high‐resolution laboratory velocity data, extend the scope of the analysis. The experiments show that partial confinement exerts a first‐order control on flow structure. Overbank and downstream discharges rapidly adjust over short length scales, providing a mechanism via which currents of varying sizes can be tuned by a channel and conform to a given channel geometry. Across a wide range of flow magnitudes and states of flow equilibration to the channel, a high‐velocity core remains confined within the channel with a constant ratio of velocity maximum height to channel depth. Ongoing overbank flow prevents any flow thickening due to ambient entrainment, allowing stable downstream flow evolution. Despite dynamical differences, the entrainment rates of partially confined and fully confined flows remain comparable for a given Richardson number.

show abstract

Section: Discussionmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 90%

The Structure and Entrainment Characteristics of Partially Confined Gravity Currents

2019

View full text Add to dashboard Cite

show abstract

“…Stagnaro and Pittaluga [58] validated the empirical relation suggested by [56] using their experimental values of the entrainment coefficient and found that it provides a good estimate.…”

Section: Water Entrainment Into Turbidity Currentmentioning

confidence: 86%

Breaching Flow Slides and the Associated Turbidity Current

Alhaddad

Labeur

Uijttewaal

2020

JMSE

View full text Add to dashboard Cite

This paper starts with surveying the state-of-the-art knowledge of breaching flow slides, with an emphasis on the relevant fluid mechanics. The governing physical processes of breaching flow slides are explained. The paper highlights the important roles of the associated turbidity current and the frequent surficial slides in increasing the erosion rate of sediment. It also identifies the weaknesses of the current breaching erosion models. Then, the three-equation model of Parker et al. is utilised to describe the coupled processes of breaching and turbidity currents. For comparison’s sake, the existing breaching erosion models are considered: Breusers, Mastbergen and Van Den Berg, and Van Rhee. The sand erosion rate and hydrodynamics of the current vary substantially between the erosion models. Crucially, these erosion models do not account for the surficial slides, nor have they been validated due to the scarcity of data on the associated turbidity current. This paper motivates further experimental studies, including detailed flow measurements, to develop an advanced erosion model. This will improve the fidelity of numerical simulations.

show abstract

“…Lock-exchange generated turbidity currents have discontinuous flow properties; hence velocity measurements must be collected instantaneously to obtain a discrete, representative velocity profile. UVP is therefore gaining popularity as a method for measuring lock-exchange turbidity currents due to its ability to measure multiple velocity profiles [8,[26][27][28]. However, it remains under-utilized for experimental studies incorporating obstacles and substrates.…”

Section: Effect Of Confinement and Obstacles On Flowmentioning

confidence: 99%

Coupling of Ultrasonic and Photometric Techniques for Synchronous Measurements of Unconfined Turbidity Currents

Wilson¹,

Friedrich

2018

Water

View full text Add to dashboard Cite

By synchronizing data collection, such as photometric and ultrasonic Doppler profiling (UVP) measurement techniques, new insights can be obtained into environmental flows, such as highly dynamic turbidity currents. We introduce a combined experimental setup, which ultimately allows a time reduction in testing programmes, and discuss the measurement advances with the help of four surface conditions we tested for unconfined turbidity currents: (a) a smooth surface; (b) a smooth surface with an obstacle present; (c) a rough surface; and (d) a rough surface with an obstacle present. We show that data from both measurement techniques indicate that a rough surface reduces global current velocities and the magnitude of turbidity current phenomena, including Kelvin-Helmholtz instabilities and lobe-and-cleft formation. However, by coupling the techniques, photometric data give valuable insight into the spatial development of instabilities, such as the grouping of lobe and cleft formations. The presence of an obstacle causes local regions of an increased and decreased velocity, but does not affect the global current velocity. Additionally, the obstacle created three local intensity maxima upstream, dissipating to two maxima downstream, supporting the presence of local eddies. The study shows that the combination of UVP and photometry is an effective way forward for obtaining detailed qualitative and quantitative insights into turbulent flow characteristics and we highlight the potential for future research.

show abstract

Velocity and concentration profiles of saline and turbidity currents flowing in a straight channel under quasi-uniform conditions

Cited by 23 publications

References 25 publications

The Structure and Entrainment Characteristics of Partially Confined Gravity Currents

The Structure and Entrainment Characteristics of Partially Confined Gravity Currents

Breaching Flow Slides and the Associated Turbidity Current

Coupling of Ultrasonic and Photometric Techniques for Synchronous Measurements of Unconfined Turbidity Currents

Contact Info

Product

Resources

About