Bar dynamics and sediment transport pulses in gravel-bed channels.

Mountain rivers exhibit sediment transport rate fluctuations that often cover more than two orders of magnitude. Bedform migration is often cited as the key process that causes giant fluctuations in the sediment transport rate. To quantify the effect of bedform migration on transport rate, we ran laboratory experiments in a 19-m long 60-cm wide flume with well-sorted gravel bed. At the flume inlet, the water discharge and the particle flux were kept constant. Experiments were conducted over long times (typically > 500 h). Sediment transport rate was monitored at the flume outlet using accelerometers. Bed topography was scanned at high spatial resolution using a laser sheet. Water depth was measured using ultrasonic probes mounted on an automated rolling carriage. We observed that, under steady state experimental conditions, bed morphology played a key part in the generation of bedload transport fluctuations. The bars migrated downstream intermittently, producing the most important pulses. When the bar position was stable for a few hours, additional pulses resulted from sediment transfer from pool to pool, in the form of sediment waves (bedload sheets). Thus, in our experiments, alternate bars formed a two-entity system (bar + pool) with two distinctive functions: the bars contributed to fix and stabilize the bed whereas the pools were the preferential zones of short-term storage and transfer of sediment.

Intermittent motion and sediment transport -- experimental and theoretical insight

Christophe Ancey

We investigate the entrainment, deposition, and motion of coarse spherical particles within a turbulent shallow water stream down a steep slope. This is an idealization of bed-load transport in mountain streams. Earlier investigations have described this kind of sediment transport using empirical correlations or concepts borrowed from continuum mechanics. The intermittent character of particle transport at low water discharges led us to consider it as a random process. Sediment transport in this regime results from the imbalance between entrainment and deposition of particles rather than from momentum balance between water and particles. We develop a birth-death immigration-emigration Markov process to describe the particle exchanges between the bed and the water stream. A key feature of the model is its long autocorrelation times and wide, frequent fluctuations in the solid discharge, a phenomenon never previously explained despite its ubiquity in both nature and laboratory experiments. We present experimental data obtained using a nearly two-dimensional channel and glass beads as a substitute for sediment. Entrainment, trajectories, and deposition were monitored using a high-speed digital camera. The empirical probability distributions of the solid discharge and deposition frequency were properly described by the theoretical model. Experiments confirmed the existence of wide and frequent fluctuations of the solid discharge, and revealed the existence of long autocorrelation time, but theory overestimates the autocorrelation times by a factor of around three. Particle velocity was weakly dependent on the fluid velocity contrary to the predictions of the theoretical model, which performs well when a single particle is moving. For our experiments, the dependence of the solid discharge on the fluid velocity is entirely controlled by the number of moving particles rather than by their velocity. We also noted significant changes in the behavior of particle transport when the bed slope or the water discharge was increased. The more vigorous the stream was, the more continuous the solid discharge became. Moreover, while 90% of the energy supplied by gravity to the stream is dissipated by turbulence for slopes lower than 10%, particles dissipate more and more energy when the bed slope is increased, but surprisingly, the dissipation rate is nearly independent of fluid velocity.

2007

Temporal evolution of bedload in a steep channel over a long duration experiment

Tamara Ghilardi, Mário Jorge Rodrigues Pereira Da Franca, Anton Schleiss

Bedload fluctuations over time in steep rivers with wide grain size distributions have been observed, even under constant sediment feeding and water discharge. Observed bedload pulses are periodical and a consequence of grain sorting. Along with bedload, flow velocity and bed morphology fluctuate in time as well. The presence of large relatively immobile boulders, such as erratic stones often present in mountain streams, have an impact on flow conditions. Their influence on these bedload fluctuations has not been studied yet, namely in what concerns the frequency and amplitude of bedload fluctuations. The influence of boulders on sediment transport and flow conditions is herein investigated by means of laboratory experiments carried out in a 8 m long and 0.25 m wide tilting flume. The detailed analysis of one set of measurements obtained during a 12.8 hours (774 minutes) test is presented in this paper. For this experiment 12 boulders of diameter D=0.075 m were randomly placed in the flume, corresponding to 3% of the flume surface initially occupied by boulders. The flume slope was set to 6.7%. Input sediment discharge was constant and equal to qs,in=0.0563 x10-3 m2/s and the liquid discharge was fixed at q=1.68 x10-2 m2/s. Sediment transport and boulder protrusion are measured regularly during the experiment. Furthermore, bulk mean flow velocities are measured every 15 minutes. Periodical bedload pulses are clearly visible on this long duration experiment. Bulk velocity and boulder protrusion are linked with the fluctuations of the bedload transport as demonstrated by correlational analysis. The period and the phase of the fluctuations are similar for all the measured variables. Observations indicate that the detected periodical fluctuations correspond to different bed states. Grain size distribution through the channel, varying in time and space, is clearly influencing these bedload pulses. During low sediment discharges, coarse stable riffles are formed. On the other hand, in high sediment fluxes the destruction of riffles followed by bed fining is observed. A detailed description of the experimental observations and an analysis of amplitude and frequency of fluctuations for this long duration test are presented in this article.

TPU2013

Period and amplitude of bedload pulses in a macro-rough channel

Tamara Ghilardi, Mário Jorge Rodrigues Pereira Da Franca, Anton Schleiss

It is known that bedload fluctuates over time in steep rivers with wide grain size distributions, even under conditions of constant sediment feed and water discharge. Bedload fluctuations, which are a consequence of grain sorting, are periodic and are related to fluctuations in the flow velocity and channel-bed morphology. The presence of large relatively immobile boulders, such as erratic blocks that are often present inmountain streams, has a strong impact on flow conditions and sediment transport. However, their influence on bedload fluctuations has not been studied. Sediment transport fluctuations were investigated in this study in a set of 38 laboratory experiments carried out on a steep tilting flume under several conditions of constant sediment andwater discharge for three different slopes (S= 6.7%, 9.9%, and 13%). Sediment transport, bulkmean flowvelocities, and variables describing the channel-bed morphologywere measured regularly during the experiments. Periodic bedload pulses were clearly visible in all of the experiments, alongwith flowvelocity and channel-bed morphology fluctuations. Correlation analysis showed that the durations of these cycleswere similar, although theywere not necessarily in phase. The pulses were characterized by their amplitude and period as a function of various boulder spatial densities and diameters.We could showthat for higher streampower the fluctuations decrease in cycle duration and in amplitude. The presence of boulders increases the stream power needed to transport a given amount of sediment, thus decreasing the bedload fluctuations.

American Geophysical Union2014

Intermittent motion and sediment transport -- experimental and theoretical insight

Christophe Ancey

2007

Temporal evolution of bedload in a steep channel over a long duration experiment

Tamara Ghilardi, Mário Jorge Rodrigues Pereira Da Franca, Anton Schleiss

TPU2013