Your search keyword '"SEDIMENT transport"' showing total 28 results

1. Substantial Overestimation of Terrestrial Water Storage Loss in Headwater Basins on Earth's Third Pole.

Author

Qiao, Baojin, Li, Na, Cui, Jiangpeng, Li, Dongfeng, Li, Mengyao, Xiang, Longwei, Borrelli, Pasquale, and Famiglietti, Jay

Subjects

*WATER management, *SEDIMENT transport, *WATER supply, *EROSION, *SEDIMENTS, *WATERSHEDS

Abstract

The Tibetan Plateau (TP) is suffering from a substantial decline in terrestrial water storage (TWS) in exorheic basins, threatening water resources that are critical for ∼2 billion people downstream. TWS changes are commonly estimated using gravity satellites through observations of the total terrestrial mass storage (TMS) change, with an implicit assumption of a negligible contribution from sediment transport. Through long‐term (2002–2017) sediment flux observations in seven headwater basins on the TP, we reveal that the gravity satellite‐derived TMS has decreased at a rate of 3.85 ± 0.23 Gt yr−1 in the seven basins, of which 0.35 ± 0.04 Gt yr−1 is contributed by sediment transport. Neglecting this contribution leads to an overestimation of the TWS loss by 10.1 ± 1.3%, equivalent to the annual water demand of an additional 0.62 million people in the surrounding nations. Regionally, the overestimation is surprisingly high in the Indus River and Yarkant River basins, reaching up to 50.8%–77.6%. Plain Language Summary: Accurate quantification of the change in the terrestrial water storage (TWS) on the Tibetan Plateau (TP) is imperative to improve the assessment of water availability that are critical for ∼2 billion people downstream. Through long‐term sediment flux observations, here we find that sediment transport makes a substantial contribution to gravity satellite‐derived TWS change in regions with a high erosion rate such as the TP, which has never been taken into consideration in previous studies. Neglecting this contribution leads to an overestimation of the TWS loss by about 10% on average for the seven headwater basins on the TP. The contribution is especially high in the Indus River and Yarkant River basins. Our findings improve the regional estimation of water availability and thus support climate adaptation and sustainable water resource management. Key Points: For the first time, we quantify the contribution of sediment transport to gravity satellite‐based estimation of TWS change on the TPNeglecting the contribution of sediment transport leads to an overestimation of the TWS loss by 10.1% on averageThe overestimated TWS loss is equivalent to the annual water demand of an additional 0.62 million people in surrounding nations [ABSTRACT FROM AUTHOR]

Published

2024

2. Vegetation‐Generated Turbulence Does Not Impact the Erosion of Natural Cohesive Sediment.

Author

Deitrick, Autumn R., Ralston, David K., Esposito, Christopher R., Baustian, Melissa M., Burgos, Maricel Beltrán, Courtois, Andrew J., and Nepf, Heidi

Subjects

*MANGROVE plants, *EROSION, *TURBULENCE, *SEDIMENTS, *SEDIMENT transport, *SUSPENDED sediments, *MANGROVE forests

Abstract

Previous studies have demonstrated that vegetation‐generated turbulence can enhance erosion rate and reduce the velocity threshold for erosion of non‐cohesive sediment. This study considered whether vegetation‐generated turbulence had a similar influence on natural cohesive sediment. Cores were collected from a black mangrove forest with aboveground biomass and exposed to stepwise increases in velocity. Erosion was recorded through suspended sediment concentration. For the same velocity, cores with pneumatophores had elevated turbulent kinetic energy compared to bare cores without pneumatophores. However, the vegetation‐generated turbulence did not increase bed stress or the rate of resuspension, relative to bare cores. It was hypothesized that the short time‐scale fluctuations associated with vegetation‐generated turbulence were not of sufficient duration to break cohesion between grains, explaining why elevated levels of turbulence associated with the pneumatophores had no impact on the erosion threshold or rate. Plain Language Summary: Mangrove habitat grows by retaining sediment. To restore these systems, it is necessary to understand how vegetation influences the transport and retention of sediment. This study used sediment cores collected from the interior of a mangrove forest to study how the aboveground roots, called pneumatophores, influence hydrodynamic conditions and sediment transport, and in particular the onset and rate of sediment erosion. Individual pneumatophores generate eddies that enhance turbulence, compared to conditions without pneumatophores. In sandy soil, vegetation‐generated turbulence can enhance erosion. However, in this study, vegetation‐generated turbulence did not increase the rate of erosion for natural cohesive (muddy) sediment, suggesting that the mangrove forest interior has naturally greater resistance to erosion and sediment loss. Key Points: For the same velocity, cores with pneumatophores had higher turbulent kinetic energy (TKE) compared to cores without pneumatophoresUnlike sands, the inception of erosion and erosion rates for cohesive sediment were better predicted by bed shear stress than by TKEModelers should parameterize erosion within vegetation differently for cohesive and non‐cohesive sediment [ABSTRACT FROM AUTHOR]

Published

2024

3. Evaluating the Effect of Morphologic Units on Fractional Sediment Mobility and Bedload Transport in a Small Pool‐Riffle Reach.

Author

Al‐Ghorani, Nisreen G., Hassan, Marwan A., and McDowell, Conor

Subjects

BED load, SEDIMENT transport, SEDIMENTS, SHEARING force, HYDRAULIC models

Abstract

This study examines the spatial pattern of fractional sediment mobility and assesses the influence of morphologic units on bedload transport in a small pool‐riffle reach with limited supply. Using a 2D hydraulic model and a subsurface‐based sediment transport model, shear stresses, fractional sediment mobility, and bedload transport were examined for flow events ranging in magnitude between 0.2Qbf and 1.5Qbf. Results reveal that while spatial variations in shear stress decrease as discharge increases, only a small proportion of the bed experiences high transport rates. At the reach scale, riffles are the primary morphological unit contributing to fully mobile sediment for all size fractions. However, at a subunit scale, there is evidence of sediment transport reversal for grains >32 mm at flows near or exceeding bankfull discharge in association with shear stress reversal. These transport reversals are important for maintaining pools despite their infrequent occurrence in the study reach. Sediment transport maps indicate that bed morphology considerably influences sediment transport at low to moderate flows. During these events, the shear stress is sensitive to local bed topography and partial mobility is the dominant transport process. In contrast, variations in bedload transport rates decrease during high flows when the flow is less sensitive to variations in bed topography and the bed becomes fully mobile. Key Points: A scaled version of a subsurface‐based model was utilized to evaluate the impact of morphologic units on fractional sediment mobilityRiffles were found to be the main source of fully mobile sediment of all sizes, with local transport reversal observed for grains >32 mmThe impact of morphologic units on bedload transport is more pronounced during low and moderate flows and diminishes during high flows [ABSTRACT FROM AUTHOR]

Published

2024

4. Turbulence Intermittency Effects on the Initiation Threshold of Sediment Motion in Natural Waters.

Author

Li, Renzhi, Wang, Ya Ping, and Gao, Shu

Subjects

SEDIMENTS, SEDIMENT transport, TURBULENCE, SHEARING force, GRAIN size

Abstract

The initiation threshold of sediment motion, a key component in quantifying sediment transport, has potential link to intermittent turbulence bursts. Here, we elaborated in situ experiments on coastal sea bottom covered with cohesive sediments, to obtain intermittency parameters. The variable "waiting time" between turbulence bursts was utilized to capture the occurrence of sediment initiation events in natural waters. A relationship between waiting time and shear stress reveals the different intermittency features of sediment flux time series before and after reaching the threshold, which can be used to determine the initiation threshold of sediment motion. Multi‐site results demonstrate the limitations of traditional empirical formulae for fine‐grained sediments, where cohesiveness becomes more pronounced as grain size decreases and the deviation can reach 600%. The empirical formula was modified using grain size, and the modified calculations were in good agreement with observed values, which will greatly assist in sediment transport and geomorphology model predictions. Plain Language Summary: As an on‐off switch for sediment transport, sediment initiation determines the redistribution of matter and the geomorphological evolution. Researchers have confirmed a link between intermittency and sediment initiation, yet how to parameterize and utilize has not been studied in depth. Here, the ability to capture sediment initiation events using intermittency metrics is verified for the first time with numerous in situ observations of high‐resolution velocity and sediment concentration data. Furthermore, a new procedure of utilizing field data to determine the initiation threshold was proposed by using the distribution relationship between the bottom shear stress and intermittency metric. Increasing differences between the newly determined threshold and empirical formula results correlate with the decrease in grain size. Such knowledge greatly helps improve the accuracy of threshold determination which in turn contributes to the accurate prediction of sediment transport models and thus engineering applications. Key Points: Field‐measured intermittency indicators effectively identify sediment motion initiation, aligning with laboratory findings on shear stressLeveraging the relationship between intermittency indicator and shear stress enables precise determination of sediment initiation thresholdWe propose a modified formula incorporating grain size to more accurately calculate the critical shear stress of fine‐grained sediments [ABSTRACT FROM AUTHOR]

Published

2024

5. Sediment–vegetation interactions determine the fate of fluvial sediment in the upper reaches of a large estuary.

Author

Palinkas, Cindy M., Gurbisz, Cassie, and Bolton, Miles C.

Subjects

*REGIONS of freshwater influence, *SEDIMENTATION & deposition, *SEDIMENTS, *SEDIMENT transport, *SEDIMENT control

Abstract

Feedbacks between sediment and plants in the submersed aquatic vegetation (SAV) beds of the Susquehanna Flats help modulate sediment delivery into the upper Chesapeake Bay from its major tributary (Susquehanna River). Recent modeling work has shown that SAV can steer the river plume, directly controlling sediment transport and fate. However, transport mechanisms likely differ between flood and non‐flood conditions and depend on event timing. An opportunity to evaluate these insights in the field occurred with several flood events in summer 2018. Sediment and biomass samples were collected after the flood in the large, continuous main SAV bed of the Flats and in smaller patches to the west of the main bed to evaluate the effect of SAV bed size (width). Sediment characteristics (grain size, organic content) and deposition rates were compared to previous observations during non‐flood conditions in the main bed in 2014–2015 and in the smaller patches in 2019. Overall, sediment deposition rates could be predicted by an empirical model including sediment load, vegetation biomass, and SAV bed width, reflecting the role of vegetation in steering the Susquehanna River plume and modulating sediment input to the upper Chesapeake Bay. Understanding spatiotemporal patterns of sedimentation is essential for realistic estimates of sediment and nutrient (especially nitrogen and carbon) storage in freshwater SAV systems, which have not received as much attention as their saltwater counterparts. [ABSTRACT FROM AUTHOR]

Published

2024

6. Characterizing Erosion and Deposition in and Around Riparian Vegetation Patches: Complex Flow Hydraulics, Sediment Supply, and Morphodynamic Feedbacks.

Author

Tranmer, Andrew W., Ji, Un, Ahn, Myeonghui, Jung, Sang Hwa, and Yager, Elowyn M.

Subjects

RIPARIAN plants, SEDIMENTS, SEDIMENTATION & deposition, EROSION, HYDRAULICS, SEDIMENT transport

Abstract

Riparian vegetation plays a fundamental role in alluvial channel evolution by modifying flow and sedimentation dynamics. To elucidate the roles of sediment supply, flow‐dependent transport capacity, and morphodynamic feedbacks on the evolution of emergent vegetation patches over a single hydrograph, we conducted two experiments with different reach‐scale sediment supplies: a high‐supply experiment (HSE) and low‐supply experiment (LSE). We measured flow velocities, bedload transport, and topographic changes around a full‐scale patch of live emergent willows in an outdoor laboratory flume. Erosion occurred in the patch‐adjacent channel areas irrespective of the sediment supply, whereas deposition within the patch interior was suppressed in the LSE and enhanced in the HSE. The magnitude of patch deposition in each experiment was controlled by the local sediment supply to the patch and local sediment mobility during each discharge in the hydrograph. The local sediment supply was affected by bed morphodynamics at the patch head, which modulated the reach‐scale sediment supply by redistributing the bedload in the channel. Sediment mobility within the patch was flow‐dependent and a function of velocity and turbulent kinetic energy. For different discharges, the velocity in the patch changed proportionally with the freestream velocity; however, the turbulent kinetic energy was more sensitive, being elevated compared with the freestream during high flows and inhibited at low flows. Therefore, deposition and erosion within vegetation patches are not simply functions of the reach‐scale sediment supply or patch flow characteristics, as is often assumed, but additionally depend on the local sediment supply to the patch interior. Plain Language Summary: Riparian vegetation in rivers and deltas is considered a primary cause of sediment deposition and channel stabilization. However, in the laboratory, we identified the physical mechanisms influencing sediment deposition and erosion and their change over a natural flow regime to illustrate that the same full‐sized willow patch can either enhance or reduce sediment deposition within the patch interior relative to the same channel without vegetation. The amount of sediment deposited in the vegetation patch depended on the velocity and turbulent kinetic energy of the water, which changed as the flow decreased. Additionally, the presence of a single vegetation patch fundamentally changed the character of the channel from depositional to erosional near the patch, indicating that more erosion occurred in adjacent channels than deposition within the patch. Deposition and erosion of the bed were also influenced by the amount of sediment supplied to the channel from upstream. This reach‐scale sediment supply was modified by a sediment mound that formed at the upstream end of the patch during high sediment supply to the channel. The mound redistributed the sediment transport within the channel and vegetation patch, revealing another physical mechanism influencing the spatial and temporal variability of bedload transport in vegetated channels. Key Points: Relative to the open depositional channel located upstream, a single vegetation patch caused channel erosion that lowered the median bed elevations by up to 640%The same vegetation patch can both inhibit and enhance interior sediment deposition depending on the flow‐dependent transport capacity and local sediment supplyMorphodynamic bed changes modulated the reach‐scale sediment supply in and around the patch by spatially redistributing bedload within the channel [ABSTRACT FROM AUTHOR]

Published

2024

7. Filtering of the Signal of Sediment Export From a Glacier by Its Proglacial Forefield.

Author

Mancini, D., Dietze, M., Müller, T., Jenkin, M., Miesen, F., Roncoroni, M., Nicholas, A. P., and Lane, S. N.

Subjects

*SUBGLACIAL lakes, *GLACIERS, *ALPINE glaciers, *SIGNAL filtering, *HAZARD mitigation, *GLOBAL warming, *SEDIMENTS, *ECOLOGICAL succession

Abstract

Alpine glaciers are rapidly retreating due to global warming and this has been associated with enhanced supply of subglacially derived sediment to downstream environments. We present the first high frequency quantitative record on how the signal of sediment exported from an Alpine glacier is filtered by its proglacial forefield. The data, covering two climatically distinct glacier melt seasons, show that the signal of subglacial bedload export is strongly filtered over short distances, unlike suspended load whose signal is less impacted. The reason is related to the interplay of short particle advection lengths with strong morphodynamic forcing. The subglacial sediment export signal is thus rapidly replaced by one combining (a) the local forcing by stream hydraulics and (b) the reworking of the proglacial braid plain itself. These findings have implications for estimating subglacial erosion rates, natural hazard mitigation, sediment management for hydropower plants and ecological succession related to rapid glacier retreat. Plain Language Summary: Alpine glaciers have been retreating at increasing rates since the early 20th century due to the current climate warming. As a consequence, new, powerful and rapidly changing rivers have developed in the newly emerged terrain in front of shrinking glaciers (i.e., proglacial forefields). These environments are known to be among the most rapidly changing landscapes on Earth. In this study we present the first combined high frequency quantitative data on sediment export from an Alpine glacier for two melt seasons with very different climatic conditions. Results show that the low potential transport distances of particles traveling on the river bed together with the continuously changing shape of these streams, rapidly modify the glacier‐dictated export signal (i.e., subglacial sediment evacuation rates in time). For sediment transported in suspension in the river, that loss of information is less evident. These findings are important for the understanding of how much, when, and which kind of sediment are delivered to the populated places downstream in the valleys, in order to mitigate natural hazards, but also for sediment management in hydropower plants and ecological succession in the context of rapid glacier retreat. The results are also key to improving estimation of glacial erosion rates. Key Points: Seismically inferred sediment transport anatomy reveals strong filtering of subglacial bedload export signal due to proglacial processesFiltering operates at a sub‐daily scale, and is due to the short advection lengths of bedload particles in the proglacial forefieldProglacial filtering is a key factor affecting (pro‐)glacial sediment transport dynamics, sediment connectivity and ecological succession [ABSTRACT FROM AUTHOR]

Published

2023

8. A Plio‐Pleistocene eustatic and storm‐controlled mixed carbonate–siliciclastic marine ramp deposit in south‐west Florida: An example of sediment homogenisation with maintenance of carbonate‐producing organisms.

Author

Missimer, Thomas M. and Hegy, Michael

Subjects

MARINE sediments, SAND, SEDIMENTS, CARBONATES, WATER depth, CARBONATE minerals, CORAL reefs & islands, SEDIMENT transport

Abstract

Mixed siliciclastic and carbonate sediments are common in the stratigraphic record, but fully homogenised mixes are not. Many occurrences of mixed sediment sequences are dominated by end‐members with stacking of 'nearly pure' lithfacies (e.g. cyclothems containing alternating sandstone, limestone and coal units). The Plio‐Pleistocene sediments within south‐west Florida provide insights into the occurrence of fully homogenised siliciclastic/carbonate deposits. In all defined environments from lagoon to supratidal to inner tidal to beach to offshore to coral reef, quartz sand coexists with carbonates. Perhaps the key feature that allowed full homogenisation of the sediments within all facies and subfacies was the relatively shallow water (<10 m), which facilitated mixing during low‐order eustatic sea‐level events and storms. However, four factors contributed to the full homogenisation of the sediment types without termination or inhibition of carbonate organism growth. These factors are (1) the shallow water allowing wave‐driven sediment transport (all environments within the wave orbital depth), (2) close proximity and perhaps irregular nature of the depositional environment boundaries, (3) low influx rate of quartz sand via longshore transport, and (4) the lack of significant terrigenous mud transport into the system. Mixing processes at the large‐scale included movement of sediments from one depositional environment to another during storms, mixing along facies boundaries, and in situ mixing within autochthonous and parautochthonous mollusc death assemblages. At the smaller scale, mixing occurred by bioturbation and diagenetic dissolution of carbonate skeletal grains during minor high sea‐level stands. [ABSTRACT FROM AUTHOR]

Published

2023

9. The Existence and Origin of Multiple Equilibria in Sand‐Mud Sediment Beds.

Author

Colina Alonso, A., van Maren, D. S., Herman, P. M. J., van Weerdenburg, R. J. A., Huismans, Y., Holthuijsen, S. J., Govers, L. L., Bijleveld, A. I., and Wang, Z. B.

Subjects

*SEDIMENTATION & deposition, *TIDAL basins, *SEDIMENTS, *SUSPENDED sediments, *COMPOSITION of sediments, *SEDIMENT transport, *EROSION

Abstract

The sediment composition of the seabed governs its mobility, hence determining sediment transport and morphological evolution of estuaries and tidal basins. Bed sediments often consist of mixtures of sand and mud, with spatial gradients in the sand/mud content. This study aims at increasing the understanding of processes driving the sediment composition in tidal basins, focusing on depositional processes. We show that bed sediments in the Wadden Sea tend to be either mud‐dominated or sand‐dominated, resulting in a bimodal distribution of the mud content where the two modes represent equilibrium conditions. The equilibria depend primarily on the sediment deposition fluxes, with bimodality originating from the dependence of suspended sand/mud concentrations on the local bed composition. Our analysis shows that bimodality is a phenomenon that is not only specific for the Wadden Sea; it can be expected for a wide range of suspended sediment concentrations and thus also in other systems worldwide. Plain Language Summary: The bottom of coastal seas is often composed of two sediment types, namely sand and mud. The evolution of the seabed, and thus of our coasts, depends on how these sediment types move. A correct representation of the spatial sand‐mud patterns in the bed is therefore essential if we want to understand and predict coastal evolution. Studying a large data set we found that sediment beds tend to be either sandy or muddy, with lower chances of finding something in between (i.e., bimodality). Although segregation of sand and mud has often been attributed to erosion processes, we found that this is mainly the result of depositional processes, and especially of the suspended sediment concentrations. Sand concentrations largely depend on local conditions, while local mud concentrations are much more affected by conditions elsewhere and/or earlier. The difference in the suspended sand and mud concentrations leads to multiple equilibria in the bed composition—resulting in the previously mentioned bimodality—for a very wide range of conditions. Therefore, we also expect bimodality and sharp sand‐mud transitions in other systems worldwide. Key Points: Mud contents in the sediment bed can be bimodally distributed, resembling preferential sand‐mud segregationBimodality represents the existence of two stable equilibrium conditions, which are a result of the deposition fluxes of sand and mudBimodality is expected for a large range of suspended sediment concentrations in sand‐mud systems [ABSTRACT FROM AUTHOR]

Published

2022

10. Does the Threshold of Sediment Motion Constrain the Width of an Incising Laboratory River?

Author

Ashley, T. C. and Strom, K.

Subjects

*RIVER sediments, *SURFACE of the earth, *SEDIMENT transport, *SEDIMENTS, *RIVER channels, *WATERSHEDS, *LABORATORIES

Abstract

A physically rational model for river width is critical to predict macroscopic landscape evolution driven by fluvial sediment transport. Growing evidence suggests that rivers widen until the stress exerted by the fluid on the bed surface is close to the critical entrainment stress of the bank material. In this study, we test the limits of this model as a closure assumption in dynamically evolving river systems. We consider a simple laboratory channel with a fixed water discharge, monodisperse bed material, no sediment supply, and an initial relief that was sufficiently large to guarantee a finite transport capacity. Over time, the transport capacity approaches zero through changes in channel morphology. Concurrent measurements of width and sediment load illustrate how theory developed for equilibrium rivers fails to predict transient channel processes. Similarity to first order trends in natural rivers suggest that many rivers could be far from equilibrium. Plain Language Summary: River channel width influences the rates and locations of large‐scale geomorphic change. Recent studies argue that channel width is set by a balance between fluid forces and gravity acting on sediment particles that make up the banks and bed. Here, we test whether this principle constrains the width of a disequilibrium laboratory river. Width remains roughly constant throughout the experiment, diverging from physical theory but mirroring observations of natural rivers. Based on this result, we suggest that many rivers on Earth's surface could be far from equilibrium. Key Points: Sediment discharge approaches zero in a laboratory river with no sediment supplyWidths depart from near‐threshold model predictionComparison with global database indicates many rivers could be far from equilibrium [ABSTRACT FROM AUTHOR]

Published

2022

11. Sediment Pickup Rate in Bare and Vegetated Channels.

Author

Xu, Yuan, Li, Danxun, and Nepf, Heidi

Subjects

*WETLANDS, *WETLAND restoration, *SEDIMENTS, *MARSHES, *SEDIMENT transport, *WATER quality, *KINETIC energy

Abstract

Understanding the influence of vegetation on flow and sediment transport is essential to wetland protection and restoration projects. Laboratory experiments were conducted to investigate the sediment pickup (or entrainment) over bare and vegetated beds with model vegetation (i.e., cylinder arrays) of different solid volume fractions, ϕ $\phi $, and diameters, d $d$. For the vegetated beds, measured pickup rate was closely correlated with turbulent kinetic energy, kt ${k}_{t}$, and τ $\tau $‐based model developed for bare channels significantly underestimated the pickup rate measured in vegetated channels. Building on previous theoretical analyses and observations, this study proposed two kt ${k}_{t}$‐based predictions for pickup rate that include the impact of both bed‐ and vegetation‐generated turbulence. The new models improve the prediction of pickup rate within vegetated regions. Plain Language Summary: Aquatic vegetation abounds in rivers, lakes, and coastal regions. It plays an important role in ecosystems, for example, it enhances water quality, stabilizes riverbanks, and promotes soil carbon storage. During the past decades, however, the area of vegetated ecosystems has significantly decreased, leading to a growing interest in wetland restoration. To improve restoration outcomes, it is essential to understand how vegetation impacts flow and sediment motion. This study revealed that traditional models describing sediment erosion in bare channels underestimated by orders of magnitude the erosion rate in vegetated regions. This was attributed to the influence of vegetation‐generated turbulence on sediment erosion. New predictions for sediment erosion rate that incorporate the influence of turbulence were proposed and validated. The new description of erosion can improve the modeling of landscape evolution and marsh restoration. Key Points: Time‐averaged bed‐shear stress models significantly underestimated sediment pickup rate in vegetated channelsNew turbulence‐based models predicted sediment pickup rate in both bare and vegetated channelsPickup rate resulting in either suspended load or bedload can be described by the same law [ABSTRACT FROM AUTHOR]

Published

2022

12. Seasonal growth and senescence of seagrass alters sediment accumulation rates and carbon burial in a coastal lagoon.

Author

Zhu, Qingguang, Wiberg, Patricia L., and McGlathery, Karen J.

Subjects

*CARBON cycle, *MARINE heatwaves, *SEAGRASSES, *SEDIMENTS, *MARINE habitats, *SEDIMENT transport, *VEGETATION dynamics

Abstract

Seagrass meadows are important carbon sinks in the global coastal carbon cycle yet are also among the most rapidly declining marine habitats. Their ability to sequester carbon depends on flow–sediment–vegetation interactions that facilitate net deposition, as well as high rates of primary production. However, the effects of seasonal and episodic variations in seagrass density on net sediment and carbon accumulation have not been well quantified. Understanding these dynamics provides insight into how carbon accumulation in seagrass meadows responds to disturbance events and climate change. Here, we apply a spatially resolved sediment transport model that includes coupling of seagrass effects on flow, waves, and sediment resuspension in a seagrass meadow to quantify seasonal rates of sediment and carbon accumulation in the meadow. Our results show that organic carbon accumulation rates were largely determined by sediment accumulation and that they both changed non‐linearly as a function of seagrass shoot density. While seagrass meadows effectively trapped sediment at meadow edges during spring–summer growth seasons, during winter senescence low‐density meadows (< 160 shoots m−2) were erosional with rates sensitive to density. Small variations in winter densities resulted in large changes in annual sediment and carbon accumulation in the meadow; meadow‐scale (hundreds of square meters) summer seagrass dieback due to marine heatwaves can result in annual erosion and carbon loss. Our findings highlight the strong temporal and spatial variability in sediment accumulation within seagrass meadows and the implications for annual sediment carbon burial rates and the resilience of seagrass carbon stocks under future climate change. [ABSTRACT FROM AUTHOR]

Published

2022

13. Topographic Roughness on Forested Hillslopes: A Theoretical Approach for Quantifying Hillslope Sediment Flux From Tree Throw.

Author

Doane, Tyler H., Edmonds, Douglas, Yanites, Brian J., and Lewis, Quinn

Subjects

*TOPOGRAPHIC maps, *SEDIMENT transport, *SURFACE topography, *SEDIMENTS, *TREES

Abstract

Wind‐driven tree throw is an observable and consequential process that suddenly moves soil downslope, inverts the soil column, and roughens the surface with pit‐mound topography. Quantifying fluxes due to tree throw is complicated by its stochastic nature and estimation requires averaging over a large area or long time. Here, we develop a theory that leads to a dimensionless metric directly measurable from high resolution topographic data. The theory explains the flux and topographic roughness as a function of tree throw production and decay rate by creep‐like processes. We then form a measurable dimensionless variable that is the ratio of fluxes due to tree throw versus creep‐like processes. Applying the theory to hillslopes in Southern Indiana, we find that tree throw accounts for 11%–18% of the hillslope sediment flux. The theoretical and observational findings provide important constraints on quantifying Critical Zone function from topographic parameters such as roughness. Plain Language Summary: When trees fall on hillslopes, they often uproot a volume of soil that is attached to the roots. Because trees usually fall downslope, this uprooted soil also moves down the hillslope, contributes to erosion, and leaves characteristic pit and mound shapes on the surface. Despite the topographic signature of the process, quantifying how much dirt trees move downslope is complicated by the randomness that drives the process. We develop a theory that explains the roughness of hillslope topography and how it relates to sediment transport rates driven by tree throw. We then map topographic roughness over a county in southern Indiana and demonstrate that tree throw accounts for 11%–18% of the sediment motions on hillslopes. Further, we demonstrate that east‐facing hillslopes tend to have more tree throw events, which coincides with the dominant wind directions and illustrates that extreme wind events drive most tree throw events in southern Indiana. Key Points: Tree throw accounts for 11%–18% of the hillslope sediment flux in southern IndianaThe expected topographic variance is a function of the ratio of tree throw rates to creep‐like diffusivityTree throw occurs more frequently on steep, east‐facing hillslopes, which is consistent with the dominant wind directions in Indiana [ABSTRACT FROM AUTHOR]

Published

2021

14. Watershed Sediment Yield Following the 2018 Carr Fire, Whiskeytown National Recreation Area, Northern California.

Author

East, Amy E., Logan, Joshua B., Dartnell, Peter, Lieber‐Kotz, Oren, Cavagnaro, David B., McCoy, Scott W., and Lindsay, Donald N.

Subjects

*LANDSLIDES, *SEDIMENT transport, *DEBRIS avalanches, *SEDIMENTS, *BATHYMETRIC maps, *WATERSHEDS

Abstract

Wildfire risk has increased in recent decades over many regions, due to warming climate and other factors. Increased sediment export from recently burned landscapes can jeopardize downstream infrastructure and water resources, but physical landscape response to fire has not been quantified for some at‐risk areas, including much of northern California, USA. We measured sediment yield from three watersheds (13–29 km2) that drain to Whiskeytown Lake, California, within the area burned by the 2018 Carr Fire. Structure‐from‐Motion photogrammetry on aerial images combined with sonar bathymetric mapping of submerged areas indicated first‐year post‐fire sediment yields of 4,080 ± 598 t/km2 (Brandy Creek), 2,700 ± 527 t/km2 (Boulder Creek), and 305 ± 58.0 t/km2 (Whiskey Creek)—some of the first post‐fire yields measured in northern California and 64, 42, and 4.8 times greater than pre‐fire yields, respectively. These were measured during a wet year and resulted largely from rilling erosion and fluvial sediment transport, without post‐fire debris flows. Rilling preferentially developed in contact with dirt roads, aided by thin soils and exposed bedrock, and on slopes vegetated by chaparral pre‐fire. The second post‐fire year (a dry year) was characterized by fluvial reworking and delta progradation of the first‐year deposits and relatively little new sediment export. First‐year sedimentation of 111,000 m3 represented minor loss of storage capacity in Whiskeytown Lake but would be detrimental to smaller reservoirs; in general, increased sediment yields from western US watersheds as fire and extreme rainfall increase will likely pose risks to water quality and storage. Plain Language Summary: Climate change is increasing wildfires across many regions, including California. Burned landscapes typically produce large amounts of sediment after a fire, which reduces water quality, decreases space for water storage in reservoirs, and sometimes produces hazardous debris flows. We investigated landscape response after the 2018 Carr Fire in northern California. Sediment yield measured in the first year after the fire (a wet year) varied among three study watersheds, ranging from one to two orders of magnitude greater than before the fire. The primary means of sediment mobilization was by water flowing over the land surface, instead of by landslides. These results will aid prediction of future fire response elsewhere in northern California, a growing research need given the increasing tendency for large fires to affect northern California. Key Points: Aerial photogrammetric and sonar bathymetric mapping quantify sediment volume change for 2 years after the major 2018 Carr Fire, CaliforniaFirst‐year post‐fire sediment yields in three watersheds were 64, 42, and 4.8 times greater than long‐term yields, some of the first post‐fire data from northern CaliforniaHillslope erosion was dominated by rilling rather than landslides; rilling commonly occurred downslope of dirt roads [ABSTRACT FROM AUTHOR]

Published

2021

15. Holocene progradation and retrogradation of the Central Texas Coast regulated by alongshore and cross‐shore sediment flux variability.

Author

Odezulu, Christopher I., Swanson, Travis, and Anderson, John B.

Subjects

HOLOCENE Epoch, SEDIMENTS, LITHOFACIES, COASTS, SEDIMENT transport, BEACH ridges, SHORELINES, SHORELINE monitoring

Abstract

Fifteen transects of sediment cores located off the central Texas coast between Matagorda Peninsula and North Padre Island were investigated to examine the offshore record of Holocene evolution of the central Texas coast. The transects extend from near the modern shoreline to beyond the toe of the shoreface. Lithology, grain size and fossil content were used to identify upper shoreface, lower shoreface, ebb‐tidal delta and marine mud lithofacies. Interpretations of these core transects show a general stratigraphic pattern across the study area that indicates three major episodes of shoreface displacement. First, there was an episode of shoreface progradation that extended up to 5 km seaward. Second, an episode of landward shoreline displacement is indicated by 3–4 km of marine mud onlap. Third, the marine muds are overlain by shoreface sands, which indicates another episode of shoreface progradation of up to 5 km seaward. Radiocarbon ages constrain the onset of the first episode of progradation to ca 6.5 ka, ending at ca 5.0 ka when the rate of sea‐level rise slowed from an average rate of 1.6–0.5 mm/yr. Results from sediment budget calculations and sediment transport modelling based on reasonable estimates of an ancient shoreline shape and wave climate indicate that the first progradation was a result of sand supplied from erosion of the offshore Colorado and Rio Grande deltas. The transgressive phase occurred between ca 4.9 ka and ca 1.6 ka and coincided with a major expansion of the Texas Mud Blanket, which resulted in burial of offshore sand sources and the shoreface being inundated with mud. The second, more recent episode of shoreface progradation began ca 500 years ago with a maximum rate of ca 6 m/yr. This most recent change signals a healing phase of coastal evolution from the late Holocene transgressive event. Currently, the shoreline along the central Texas coast is retreating landward at an average rate of 0.30 m/yr, indicating that the second progradation event has ended. [ABSTRACT FROM AUTHOR]

Published

2021

16. Clay minerals of surface sediments from the lower Bengal Fan: Implications for provenance identification and transport processes.

Author

Sun, Xingquan, Liu, Shengfa, Fang, Xisheng, Li, Jingrui, Cao, Peng, Zhao, Guangtao, Khokiattiwong, Somkiat, Kornkanitnan, Narumol, and Shi, Xuefa

Subjects

*CLAY minerals, *SEDIMENTS, *SEDIMENT transport, *SEDIMENT control, *ILLITE, *PROVENANCE (Geology), *MONTMORILLONITE

Abstract

Based on the clay mineral assemblages of 98 surface sediments from the lower Bengal Fan, we carried out a quantitative provenance identification and discussed the potential transport processes of fine fractions with the support of the hydrodynamic environment. Illite is the dominant clay mineral in the study area, with an average of 51%, followed by kaolinite, with an average of 20%, while chlorite and smectite account for averages of 17 and 11%, respectively. The study area can be divided into two provinces based on the clay mineral assemblages: Province I, located in the western part of the study area, has relatively higher smectite content, while province II, located in the eastern part, shows higher illite content. The Ganges–Brahmaputra (Himalayan) and the Godavari–Krishna (Indian Peninsula) are suggested to be the major provenances, and the average relative contributions of the Himalayan source and the Indian source are 76 and 24%, respectively. Sediments in province II receive more sediment from the Himalayan source, with an average contribution of 84%, while the Indian source mainly contributed to province I, with an average contribution rate of 32%. The Indian Peninsula materials are predominantly conveyed to the study area by the northeast monsoon circulation, and the relative contribution gradually decreases from northwest to southeast in the lower Bengal Fan. However, most of the Himalayan material is transported to the study area by the southwest monsoon. Our research indicates that the seasonal hydrodynamic pattern of the Northeast Indian Ocean plays an important role in controlling modern sediment transport in the Bay of Bengal, causing terrestrial materials from different sources to show significantly different spatial distribution characteristics. [ABSTRACT FROM AUTHOR]

Published

2020

17. Sediment Routing and Floodplain Exchange (SeRFE): A Spatially Explicit Model of Sediment Balance and Connectivity Through River Networks.

Author

Gilbert, Jordan T. and Wilcox, Andrew C.

Subjects

*SEDIMENTS, *RIVER sediments, *FLOODPLAINS, *GEOSPATIAL data, *SEDIMENT transport, *WATERSHEDS

Abstract

Sediment regimes, i.e., the processes that recruit, transport, and store sediment, create the physical habitats that underpin river‐floodplain ecosystems. Natural and human‐induced disturbances that alter sediment regimes can have cascading effects on river and floodplain morphology, ecosystems, and a river's ability to provide ecosystem services, yet prediction of the response of sediment dynamics to disturbance is challenging. We developed the Sediment Routing and Floodplain Exchange (SeRFE) model, which is a network‐based, spatially explicit framework for modeling sediment recruitment to and subsequent transport through drainage networks. SeRFE additionally tracks the spatially and temporally variable balance between sediment supply and transport capacity. Simulations using SeRFE can account for various types of watershed disturbance and for channel‐floodplain sediment exchange. SeRFE is simple, adaptable, and can be run with widely available geospatial data and limited field data. The model is driven by real or user‐generated hydrographs, allowing the user to assess the combined effects of disturbance, channel‐floodplain interactions and particular flow scenarios on the propagation of disturbances throughout a drainage network, and the resulting impacts to reaches of interest. We tested the model in the Santa Clara River basin, Southern California, in subbasins affected by large dams and wildfire. Model results highlight the importance of hydrologic conditions on postwildfire sediment yield and illustrate the spatial extent of dam‐induced sediment deficit during a flood. SeRFE can provide contextual information on reach‐scale sediment balance conditions, sensitivity to altered sediment regimes, and potential for morphologic change for managers and practitioners working in disturbed watersheds. Plain Language Summary: Understanding how sediment moves through watersheds is important for not only landscape evolution but also natural‐resource management. Natural and human‐caused disturbances like dams or wildfires can alter sediment connectivity in watersheds, which in turn can alter habitat and ecosystem services. Modeling approaches to simulate sediment movement through watersheds and how sediment dynamics respond to disturbance are important for managers. Here we present a new model, the Sediment Routing and Floodplain Exchange (SeRFE) model. SeRFE allows users to assess how a river reach may respond to different flow and disturbance scenarios. We tested the model in a Southern California watershed, where outputs highlighted how a wildfire changed sediment output and dams caused sediment deficit. Key Points: Riverine practitioners need tools to understand sediment regimes in rivers and how disturbance alters themSeRFE is spatially explicit and simulates sediment recruitment, transport, and storage at the reach‐scale, applied across drainage basinsSimulations suggest wildfire‐induced sediment yield depends on hydrologic conditions and illustrate the extent of dam impacts on sediment [ABSTRACT FROM AUTHOR]

Published

2020

18. Increased Subglacial Sediment Discharge in a Warming Climate: Consideration of Ice Dynamics, Glacial Erosion, and Fluvial Sediment Transport.

Author

Delaney, Ian and Adhikari, Surendra

Subjects

*SEDIMENT transport, *GLACIAL erosion, *GLACIOLOGY, *ALPINE glaciers, *SEDIMENTS, *SEDIMENT control

Abstract

We evaluate changes to subglacial sediment discharge during glacier retreat by considering ice dynamics, bedrock erosion, and sediment transport processes. Coupling these components together within a single framework, we simulate sediment discharge from synthetic alpine glaciers experiencing accelerated glacier melt for 100 years. We find that sediment discharge increases by about 8 times the steady glacier values by the end of the simulation. The enhanced sediment discharge persists through peak water discharge and despite annual bedrock erosion volume decreasing by approximately 30% from the initial value. The greater sediment discharge results from increased melt at the glaciers' higher region, where transport was limited prior to glacier retreat. These findings suggest that large increases in sediment discharge may occur as glaciers retreat. The magnitude of the sediment discharge increase primarily depends on the quantity of sediment stored subglacially. Plain Language Summary: Changes to sediment discharge from glaciers can dramatically impact downstream communities and ecosystems. We account for two primary processes that largely control to sediment discharge from glaciers: (1) bedrock erosion, which creates sediment below the glacier and (2) the ability of meltwater below the glacier to carry this sediment. To understand the potential changes in sediment discharge as glaciers retreat, we link numerical models of both processes and run them in a scenario that complies with ongoing climate warming. In the scenario, we find that sediment discharge increases dramatically, despite smaller quantities of sediment being produced by bedrock erosion. This is because more meltwater higher on the glaciers increases sediment transport in these upper regions. Results here suggest that future subglacial sediment discharge depends on the amount of sediment that already exists below glaciers. Large increases in subglacial sediment discharge are possible. Key Points: We present a coupled system of models that represent ice dynamics, bedrock erosion, and sediment transport processesLarge increases in subglacial sediment discharge occur in response to simulated glacier retreatRising equilibrium line altitudes drive increased sediment discharge by allowing meltwater to access greater amounts of subglacial sediment [ABSTRACT FROM AUTHOR]

Published

2020

19. Role of eelgrass on bed‐load transport and sediment resuspension under oscillatory flow.

Author

Marin‐Diaz, Beatriz, Bouma, Tjeerd J., and Infantes, Eduardo

Subjects

*BED load, *SUSPENDED sediments, *ORBITAL velocity, *SEDIMENT transport, *ZOSTERA marina, *SEDIMENTS

Abstract

Coastal vegetation is widely attributed to stabilize sediment. While most studies focused on how canopy causes flow reduction and thereby affects sediment dynamics, the role of roots and rhizomes on stabilizing the surface sediment has been less well studied. This study aims to quantify interactions between above‐ and belowground biomass of eelgrass (i.e., living Zostera marina plants and mimics) with surface sediment erosion (i.e., bed load and suspended load), under different hydrodynamic forcing that was created using a wave flume. Belowground biomass played an important role preventing bed‐load erosion, by roughly halving the amount of sediment transported after being exposed to maximal orbital velocities of 27 cm s−1, with and without canopy. Surprisingly, for suspended sediment transport, we found opposite effects. In the presence of eelgrass, the critical erosion threshold started at lower velocities than on bare sediment, including sand and mud treatments. Moreover, in muddy systems, such resuspension reduced the light level below the minimum requirement of Z. marina. This surprising result for sediment resuspension was ascribed to a too small eelgrass patch for reducing waves but rather showing enhanced turbulence and scouring at meadow edges. Overall, we conclude that the conservation of the existent eelgrass meadows with developed roots and rhizomes is important for the sediment stabilization and the meadow scale should be taken into account to decrease sediment resuspension. [ABSTRACT FROM AUTHOR]

Published

2020

20. Sediment Supply Explains Long‐Term and Large‐Scale Patterns in Salt Marsh Lateral Expansion and Erosion.

Author

Ladd, Cai J.T., Duggan‐Edwards, Mollie F., Bouma, Tjeerd J., Pagès, Jordi F., and Skov, Martin W.

Subjects

*SALT marshes, *SEDIMENT transport, *SEDIMENTS, *AERIAL photographs, *COASTAL changes, *HYDROLOGY

Abstract

Salt marshes often undergo rapid changes in lateral extent, the causes of which lack common explanation. We combine hydrological, sedimentological, and climatological data with analysis of historical maps and photographs to show that long‐term patterns of lateral marsh change can be explained by large‐scale variation in sediment supply and its wave‐driven transport. Over 150 years, northern marshes in Great Britain expanded while most southern marshes eroded. The cause for this pattern was a north to south reduction in sediment flux and fetch‐driven wave sediment resuspension and transport. Our study provides long‐term and large‐scale evidence that sediment supply is a critical regulator of lateral marsh dynamics. Current global declines in sediment flux to the coast are likely to diminish the resilience of salt marshes and other sedimentary ecosystems to sea level rise. Managing sediment supply is not common place but may be critical to mitigating coastal impacts from climate change. Plain Language Summary: Salt marshes are valuable ecosystems for human societies and are especially vulnerable to losses caused by human activity and climate change. Little is known about how the size of marshes has changed in response to disturbance over large‐ and long‐term scales. We used historical maps and aerial photographs to capture 150 years of change in marsh area extent in 25 estuaries and ca. 100 marshes across Great Britain. We then related the rates of marsh change to existing data on hydrology, biology, climate, sediment supply, and other variables, to find out which elements best explained patterns of erosion and expansion for the period between 1967 and 2016. We found a shift from long‐term marsh erosion in the southeast to long‐term marsh expansion in the northwest of Great Britain. This pattern was explained by a south‐to‐north gradient of increasing sediment flux into marshes and wave fetch lengths which helps transport sediment onto marshes. Our study demonstrates how sediment supply should be monitored and managed to preserve salt marsh extent into the future. Key Points: Sea level rise alone does not explain marsh lateral changes over the past 150 yearsSediment flux is by far the strongest indicator of long‐term lateral changes in salt marsh extentSmall increases in fetch length may boost marsh expansion through stimulating wind‐driven sediment transport onto marshes [ABSTRACT FROM AUTHOR]

Published

2019

21. Modeling the Suspended Sediment Transport in a Very Wide, Shallow, and Microtidal Estuary, the Río de la Plata, Argentina.

Author

Moreira, Diego and Simionato, Claudia G.

Subjects

*SUSPENDED sediments, *SEDIMENT transport, *SEDIMENTATION & deposition, *ESTUARIES, *WIND waves, *SEDIMENTS, *FLOCCULATION

Abstract

The impact of the diverse processes responsible for the distribution of suspended sediments in the wide, shallow, and microtidal Río de la Plata estuary and the adjacent shelf is studied by means of a set of process-oriented numerical simulations. Model results show that the large width and the geometry of the estuary play a major role in the sedimentation processes. The widening and deepening of the estuary drives a significant reduction in current speeds at (i) the confluence of the tributaries and (ii) downstream Barra del Indio Shoal. Thus, sediment deposition enhances downstream those areas. Even though tides are of small amplitude in the study area, they have a significant impact on lateral mixing and resuspension of the bottom sediments. Resuspension augments the concentration of fine sediments in the layers close to the bottom, but tidal energy is not enough to lift them to the surface. Winds (which can be quite strong over this area) enhance horizontal mixing, smoothing the pattern produced by tides. Wind waves increase the concentration of sediment by vertical mixing, and their effect is most evident along the southern coast where wind waves lift the sediments resuspended by tides to the surface. The estuarine circulations associated to the bottom salinity front acts retaining sediments upstream the Barra del Indio Shoal, where estuarine currents and flocculation play an important role in sediment deposition. [ABSTRACT FROM AUTHOR]

Published

2019

22. Quantifying carbonate sediment mixing across a formational boundary, an example from the Late Pleistocene Miami Limestone.

Author

McNeill, Donald F., Pederson, Chelsea, Brownlow, Dustin, Klaus, James S., and Blackwelder, Patricia

Subjects

MARINE sediments, SEDIMENTS, LIMESTONE, MARINE transgression, SEDIMENT transport, CARBONATE minerals, CARBONATES, FOSSIL microorganisms

Abstract

Holocene marine sediment from proto‐Florida Bay has been eroded, suspended, transported landward and has infiltrated downward (to 1 m depth) to fill secondary pores in subaerially exposed Late Pleistocene limestone. Sediment mineralogy (up to 95% aragonite), sediment texture (mostly needle‐like, <15 µm), and bulk sediment stable‐isotope values (upward trend in δ18O from −1 to −3‰ and δ13C from 3.5 to −2‰) of infill sediment is used to document inter‐stratal movement of sediment ahead of marine transgression. Nearby Florida Bay probably supplied needle‐like aragonite crystals by a storm surge mechanism that transported sediment landward and perhaps sorted the marine mud fraction. Currently, the core site is covered by freshwater microbial lime mud with a texture different than most infill sediment. That sediment crosses a formational and sequence boundary can have several implications: microfossil displacement; sedimentologic interpretation of mixed mud and sand‐size grains; porosity and permeability reduction; and associated diagenesis with perched ground water. If sediment infiltration is recognized in core and thin section, these mud‐filled pores can aid in recognition of subaerial exposure. Stratigraphically, the occurrence of marine sediments landward of the shoreline and below freshwater deposits may be interpreted as the result of a rapid rise and fall of sea level. [ABSTRACT FROM AUTHOR]

Published

2019

23. The wind‐driven formation of cross‐shelf sediment plumes in a large lake.

Author

McKinney, Paul, Austin, Jay, and Fai, Gills

Subjects

*SEDIMENT transport, *SEDIMENTS, *FLOW meters, *REMOTE sensing, *LAKES, *TURBIDITY, *RAINFALL intensity duration frequencies

Abstract

Wind‐driven turbidity plumes frequently occur in the western arm of Lake Superior and may represent a significant cross‐shelf transport mechanism for sediment, nutrient, and biota. Here, we characterize a plume that formed in late April 2016 using observations from in situ sensors and remote sensing imagery, and estimate the volume of cross‐shelf transport using both the observations and an idealized analytical model of plume formation. The steady‐state, barotropic model is used to determine a relationship between the intensity and duration of a wind event and the volume of water transported from nearshore to offshore during the event. The model transport is the result of nearshore flow in the direction of the wind and a pressure‐gradient‐driven counter flow in the deeper offshore waters, consistent with observations. The volume of offshore transport associated with the 2016 plume is estimated by both methods to have been on the order of 1010 m3. Analysis of similar events from 2008 to 2016 shows a strong relationship between specific wind impulse and plume volume. Differences in the intensity and duration of individual events as well as ice cover, which prevents plume formation, lead to interannual variability of offshore transport ranging over an order of magnitude and illustrates how wind‐driven processes may contribute to interannual variability of ecosystem functioning. [ABSTRACT FROM AUTHOR]

Published

2019

24. Predator, prey, and substrate interactions: the role of faunal activity and substrate characteristics.

Author

Mathers, K. L., Rice, S. P., and Wood, P. J.

Subjects

PREDATION, SUBSTRATES (Materials science), GEOMORPHOLOGY, SEDIMENTS, PACIFASTACUS leniusculus

Abstract

Many taxa possess a range of strategies to reduce the risk of predation, including actively seeking suitable refuge habitats; however, the global spread of invasive species may disrupt these behavioral responses. In lotic ecosystems, interstitial spaces in the substrate are important refugia for small organisms. Some predators are ecosystem engineers that exhibit zoogeomorphic agency--the ability to modify the geomorphology of their environment. It is therefore possible that direct ecological effects of predators on prey may be realized through modifications to the prey's habitat, including the availability of refugia, by predators that are zoogeomorphic agents or via external stressors such as fine sediment loading. This study examined three research questions in a mesocosm study across a gradient of sediment-stress treatments: (1) What affects do predators (Pacifastacus leniusculus, invasive crayfish) and prey (Gammarus pulex, amphipods) have on the ingress of fine sediment into gravel substrates and therefore on available interstitial refugia? (2) Do prey taxa seek refuge from (invasive) predators in the form of vertical movement into subsurface sediments? and (3) How does fine sediment ingress influence predator--prey interactions and prey survival through predator avoidance behavior. Here, we provide direct evidence demonstrating that fine sediment ingress into gravel river beds can be facilitated by zoogeomorphic activity with P. leniusculus increasing the infiltration of fine sand particles (but not coarse sand) during foraging activities. Predator--prey interactions were found to be a primary factor mediating zoogeomorphic activity, with the isolation of crayfish from prey (G. pulex) leading to increased fine sand ingress. When present with signal crayfish, G. pulex displayed vertical avoidance behavior, entering subsurface substrates to evade predation by P. leniusculus. Coarse sand treatments resulted in higher predation rates of G. pulex, most likely due to clogging of interstitial pore spaces between gravels limiting the effectiveness of the prey's vertical avoidance behavior strategy. A new conceptual model that captures the interactions between predator, prey, zoogeomorphic processes and habitat availability is presented. This model highlights how predator--prey interactions can be strongly mediated by dynamic bi-directional interactions between organisms and the physical environment they inhabit as ecological and geomorphological processes are intrinsically linked. [ABSTRACT FROM AUTHOR]

Published

2019

25. Autonomous bed-sediment imaging-systems for revealing temporal variability of grain size.

Author

Buscombe, Daniel, Rubin, David M., Lacy, Jessica R., Storlazzi, Curt D., Hatcher, Gerald, Chezar, Henry, Wyland, Robert, and Sherwood, Christopher R.

Subjects

MARINE sediments, SEDIMENTS, GRAIN size, VIDEO microscopy, SEDIMENT transport

Abstract

We describe a remotely operated video microscope system, designed to provide high-resolution images of seabed sediments. Two versions were developed, which differ in how they raise the camera from the seabed. The first used hydraulics and the second used the energy associated with wave orbital motion. Images were analyzed using automated frequency-domain methods, which following a rigorous partially supervised quality control procedure, yielded estimates to within 20% of the true size as determined by on-screen manual measurements of grains. Long-term grain-size variability at a sandy inner shelf site offshore of Santa Cruz, California, USA, was investigated using the hydraulic system. Eighteen months of high frequency (min to h), high-resolution (µm) images were collected, and grain size distributions compiled. The data constitutes the longest known high-frequency record of seabed-grain size at this sample frequency, at any location. Short-term grain-size variability of sand in an energetic surf zone at Praa Sands, Cornwall, UK was investigated using the 'wave-powered' system. The data are the first high-frequency record of grain size at a single location of a highly mobile and evolving bed in a natural surf zone. Using this technology, it is now possible to measure bed-sediment-grain size at a time-scale comparable with flow conditions. Results suggest models of sediment transport at sandy, wave-dominated, nearshore locations should allow for substantial changes in grain-size distribution over time-scales as short as a few hours. [ABSTRACT FROM AUTHOR]

Published

2014

26. Interactive effects of grazing and burning on wind- and water-driven sediment fluxes: rangeland management implications.

Author

Field, Jason P., Breshears, David D., Whicker, Jeffrey J., and Zou, Chris B.

Subjects

SEDIMENTS, GRAZING, BURNING of land, ANALYSIS of variance, MEAN value theorems

Abstract

The article presents a study on the effects of the implementation and utilization of various grazing and burning practices on wind- and water-driven sediment fluxes in Arizona. The study tested for significant differences in the mean values of wind- and wind-driven sediment transport in burned, grazed, burned and grazed, and undisturbed plots using a one-way analysis of variance (ANOVA). Results showed that grazing increased the wind : water sediment transport ratio but decreased in burning.

Published

2011

27. Sediment and nutrient dynamics following a low-head dam removal at Murphy Creek, California.

Author

Ahearn, Dylan S. and Dahlgren, Randy A.

Subjects

*DAM retirement, *SEDIMENT transport, *SEDIMENTS, *PHOSPHATES, *BIOTIC communities

Abstract

We studied the impact of the removal of a 3-m dam on sediment and nutrient export. In the year after dam removal, sediment and nitrogen (N) export increased by an order of magnitude over the previous 2-yr mean. Longitudinal surface water samples were collected, sediments were cored, and the channel was surveyed during different seasons to determine the mechanisms driving sediment and nutrient dynamics in the recovering system. The majority of sediment transport occurred in pools and in the lowest 50 m of the 620-m restored reach. Phosphate export occurred primarily during large storms, with the restored reach acting as a phosphate sink during most flow conditions. The majority of surface water N originated from areas within the sediment wedge that had high extractable N concentrations (average NH4-N - 50 µg g-1 and NO3-N = 38 µg g-1) and dried out on a seasonal basis. Near the former dam site, year-round water saturation apparently inhibited nitrification and export of N as nitrate. This wetland area was the only portion of the restored reach that was an ammonium sink. After dam removal, N leaching from sediments occurred in autumn 2003 and again during the subsequent autumn, suggesting that N leaching from reservoir sediments is largely a seasonal process that may affect downstream aquatic ecosystems for a number of years. [ABSTRACT FROM AUTHOR]

Published

2005

28. Characterization of spatial heterogeneity in underwater soundscapes at the river segment scale.

Author

Tonolla, Diego, Lorang, Mark S., Heutschi, Kurt, Gotschalk, Chris C., and Tockner, Klement

Subjects

*ACOUSTIC signal processing, *SEDIMENT transport, *SOUND pressure, *AERODYNAMIC load, *SEDIMENTS

Abstract

The patterns of underwater acoustic signals, called soundscapes, were characterized at the river segment scale. A hydrophone was mounted onto the frame of an inflatable multihull raft and held just below the water's surface while floating for 5-24 km to continuously record acoustic signals along the longitudinal axis of the main channel (thalweg) of five hydro-geomorphologically different river segments in Italy, Switzerland, and the United States of America. The river segments could be clearly distinguished based on sound pressure level (SPL), sound variability, and the spatial organization of the acoustic signal (10 octave bands: 0.0315-16 kHz). The spatial soundscape diversity between river segments was most likely related to the organization of turbulence along the segment length (distance between rapids) and to sound source (hydraulic turbulence or local sediment transport). Hydraulically and morphologically heterogeneous segments revealed more complex soundscapes than more homogeneous ones. Higher flow levels resulted in higher SPLs over most frequency bands. The acoustic variability of single octave bands increased from base to intermediate flow, while it decreased from intermediate to bankfull flow. The pulsating sound produced by breaking and reforming turbulent waves on flow obstacles was associated with SPL peaks and high acoustic variability in midrange frequency bands (0.063-0.5 kHz), whereas high-frequency SPLs (1-16 kHz) were related to particle collisions during streambed sediment transport. Underwater soundscapes provide an independent measure to quantify habitat heterogeneity and spatial habitat organization that can be applied to river corridors at the segment scale. [ABSTRACT FROM AUTHOR]

Published

2011