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1. Benthic biology influences sedimentation in submarine channel bends: Coupling of biology, sedimentation and flow

Author

Azpiroz‐Zabala, M., Sumner, E. J., Cartigny, M. J. B., Peakall, J., Clare, M. A., Darby, S. E., Parsons, D. R., Dorrell, R. M., Özsoy, E., Tezcan, D., Wynn, R. B., Johnson, J., Azpiroz‐Zabala, M., Sumner, E. J., Cartigny, M. J. B., Peakall, J., Clare, M. A., Darby, S. E., Parsons, D. R., Dorrell, R. M., Özsoy, E., Tezcan, D., Wynn, R. B., and Johnson, J.

Abstract

Submarine channels are key features for the transport of flow and nutrients into deep water. Previous studies of their morphology and channel evolution have treated these systems as abiotic, and therefore assume that physical processes are solely responsible for morphological development. Here, a unique dataset is utilised that includes spatial measurements around a channel bend that hosts active sediment gravity flows. The data include flow velocity and density, alongside bed grain size and channel-floor benthic macrofauna. Analysis of these parameters demonstrate that while physical processes control the broadest scale variations in sedimentation around and across the channel, benthic biology plays a critical role in stabilising sediment and trapping fines. This leads to much broader mixed grain sizes than would be expected from purely abiotic sedimentation, and the maintenance of sediment beds in positions where all the sediment should be actively migrating. Given that previous work has also shown that submarine channels can be biological hotspots, then the present study suggests that benthic biology probably plays a key role in channel morphology and evolution, and that these need to be considered both in the modern and when considering examples preserved in the rock record.

Published
2024

2. Turbidity currents can dictate organic carbon fluxes across river‐fed fjords: An example from Bute Inlet (BC, Canada)

Author

Hage, S., Galy, V. V., Cartigny, M. J. B., Heerema, C., Heijnen, M. S., Acikalin, S., Clare, M. A., Giesbrecht, I., Gröcke, D. R., Hendry, A., Hilton, R. G., Hubbard, S. M., Hunt, J. E., Lintern, D. G., McGhee, C., Parsons, D. R., Pope, E. L., Stacey, C. D., Sumner, E. J., Tank, S., Talling, P. J., Hage, S., Galy, V. V., Cartigny, M. J. B., Heerema, C., Heijnen, M. S., Acikalin, S., Clare, M. A., Giesbrecht, I., Gröcke, D. R., Hendry, A., Hilton, R. G., Hubbard, S. M., Hunt, J. E., Lintern, D. G., McGhee, C., Parsons, D. R., Pope, E. L., Stacey, C. D., Sumner, E. J., Tank, S., and Talling, P. J.

Abstract

The delivery and burial of terrestrial particulate organic carbon (OC) in marine sediments is important to quantify, because this OC is a food resource for benthic communities, and if buried it may lower the concentrations of atmospheric CO2 over geologic timescales. Analysis of sediment cores has previously shown that fjords are hotspots for OC burial. Fjords can contain complex networks of submarine channels formed by seafloor sediment flows, called turbidity currents. However, the burial efficiency and distribution of OC by turbidity currents in river-fed fjords had not been investigated previously. Here, we determine OC distribution and burial efficiency across a turbidity current system within Bute Inlet, a fjord in western Canada. We show that 62% ± 10% of the OC supplied by the two river sources is buried across the fjord surficial (30–200 cm) sediment. The sandy subenvironments (channel and lobe) contain 63% ± 14% of the annual terrestrial OC burial in the fjord. In contrast, the muddy subenvironments (overbank and distal basin) contain the remaining 37% ± 14%. OC in the channel, lobe, and overbank exclusively comprises terrestrial OC sourced from rivers. When normalized by the fjord’s surface area, at least 3 times more terrestrial OC is buried in Bute Inlet, compared to the muddy parts of other fjords previously studied. Although the long-term (>100 years) preservation of this OC is still to be fully understood, turbidity currents in fjords appear to be efficient at storing OC supplied by rivers in their near-surface deposits.

Published
2022

3. Turbidity currents can dictate organic carbon fluxes across river‐fed fjords: An example from Bute Inlet (BC, Canada)

Author

Hage, S., Galy, V. V., Cartigny, M. J. B., Heerema, C., Heijnen, M. S., Acikalin, S., Clare, M. A., Giesbrecht, I., Gröcke, D. R., Hendry, A., Hilton, R. G., Hubbard, S. M., Hunt, J. E., Lintern, D. G., McGhee, C., Parsons, D. R., Pope, E. L., Stacey, C. D., Sumner, E. J., Tank, S., Talling, P. J., Hage, S., Galy, V. V., Cartigny, M. J. B., Heerema, C., Heijnen, M. S., Acikalin, S., Clare, M. A., Giesbrecht, I., Gröcke, D. R., Hendry, A., Hilton, R. G., Hubbard, S. M., Hunt, J. E., Lintern, D. G., McGhee, C., Parsons, D. R., Pope, E. L., Stacey, C. D., Sumner, E. J., Tank, S., and Talling, P. J.

Abstract

The delivery and burial of terrestrial particulate organic carbon (OC) in marine sediments is important to quantify, because this OC is a food resource for benthic communities, and if buried it may lower the concentrations of atmospheric CO2 over geologic timescales. Analysis of sediment cores has previously shown that fjords are hotspots for OC burial. Fjords can contain complex networks of submarine channels formed by seafloor sediment flows, called turbidity currents. However, the burial efficiency and distribution of OC by turbidity currents in river-fed fjords had not been investigated previously. Here, we determine OC distribution and burial efficiency across a turbidity current system within Bute Inlet, a fjord in western Canada. We show that 62% ± 10% of the OC supplied by the two river sources is buried across the fjord surficial (30–200 cm) sediment. The sandy subenvironments (channel and lobe) contain 63% ± 14% of the annual terrestrial OC burial in the fjord. In contrast, the muddy subenvironments (overbank and distal basin) contain the remaining 37% ± 14%. OC in the channel, lobe, and overbank exclusively comprises terrestrial OC sourced from rivers. When normalized by the fjord’s surface area, at least 3 times more terrestrial OC is buried in Bute Inlet, compared to the muddy parts of other fjords previously studied. Although the long-term (>100 years) preservation of this OC is still to be fully understood, turbidity currents in fjords appear to be efficient at storing OC supplied by rivers in their near-surface deposits.

Published
2022

4. Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits

Author

Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., Talling, P. J., Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., and Talling, P. J.

Abstract

Burial of terrestrial biospheric particulate organic carbon in marine sediments removes CO2 from the atmosphere, regulating climate over geologic time scales. Rivers deliver terrestrial organic carbon to the sea, while turbidity currents transport river sediment further offshore. Previous studies have suggested that most organic carbon resides in muddy marine sediment. However, turbidity currents can carry a significant component of coarser sediment, which is commonly assumed to be organic carbon poor. Here, using data from a Canadian fjord, we show that young woody debris can be rapidly buried in sandy layers of turbidity current deposits (turbidites). These layers have organic carbon contents 10x higher than the overlying mud layer, and overall, woody debris makes up >70% of the organic carbon preserved in the deposits. Burial of woody debris in sands overlain by mud caps reduces their exposure to oxygen, increasing organic carbon burial efficiency. Sandy turbidity current channels are common in fjords and the deep sea; hence we suggest that previous global organic carbon burial budgets may have been underestimated.

Published
2020
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5. Novel Acoustic Method Provides First Detailed Measurements of Sediment Concentration Structure Within Submarine Turbidity Currents

Author

Simmons, S. M. (author), Azpiroz Zabala, M. (author), Cartigny, M. J.B. (author), Clare, M. A. (author), Cooper, C. (author), Parsons, D. R. (author), Pope, E. L. (author), Sumner, E. J. (author), Talling, P. J. (author), Simmons, S. M. (author), Azpiroz Zabala, M. (author), Cartigny, M. J.B. (author), Clare, M. A. (author), Cooper, C. (author), Parsons, D. R. (author), Pope, E. L. (author), Sumner, E. J. (author), and Talling, P. J. (author)

Abstract

Turbidity currents transport prodigious volumes of sediment to the deep sea. But there are very few direct measurements from oceanic turbidity currents, ensuring they are poorly understood. Recent studies have used acoustic Doppler current profilers (ADCPs) to measure velocity profiles of turbidity currents. However, there were no detailed measurements of sediment concentration, which is a critical parameter because it provides the driving force and debate centers on whether flows are dilute or dense. Here we provide the most detailed measurements yet of sediment concentration in turbidity currents via a new method using dual-frequency acoustic backscatter ADCP data. Backscatter intensity depends on size and concentration of sediment, and we disentangle these effects. This approach is used to document the internal structure of turbidity currents in Congo Canyon. Flow duration is bimodal, and some flows last for 5–10 days. All flows are mainly dilute (<10 g/L), although faster flows contain a short-lived initial period of coarser-grained or higher-concentration flow within a few meters of the bed. The body of these flows tends toward a maximum speed of 0.8–1 m/s, which may indicate an equilibrium in which flow speeds suspend available sediment. Average sediment concentration and flow thickness determine the gravitational driving force, which we then compared to average velocities. This comparison suggests surprisingly low friction values, comparable to or less than those of major rivers. This new approach therefore provides fundamental insights into one of the major sediment transport processes on Earth., Applied Geology

Published
2020
Full Text
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6. Novel acoustic method provides first detailed measurements of sediment concentration structure within submarine turbidity currents

Author

Simmons, S. M., Azpiroz‐Zabala, M., Cartigny, M. J .B., Clare, M. A., Cooper, C., Parsons, D. R., Pope, E. L., Sumner, E. J., Talling, P. J., Simmons, S. M., Azpiroz‐Zabala, M., Cartigny, M. J .B., Clare, M. A., Cooper, C., Parsons, D. R., Pope, E. L., Sumner, E. J., and Talling, P. J.

Abstract

Turbidity currents transport prodigious volumes of sediment to the deep sea. But there are very few direct measurements from oceanic turbidity currents, ensuring they are poorly understood. Recent studies have used acoustic Doppler current profilers (ADCPs) to measure velocity profiles of turbidity currents. However, there were no detailed measurements of sediment concentration, which is a critical parameter because it provides the driving force and debate centers on whether flows are dilute or dense. Here we provide the most detailed measurements yet of sediment concentration in turbidity currents via a new method using dual‐frequency acoustic backscatter ADCP data. Backscatter intensity depends on size and concentration of sediment, and we disentangle these effects. This approach is used to document the internal structure of turbidity currents in Congo Canyon. Flow duration is bimodal, and some flows last for 5–10 days. All flows are mainly dilute (<10 g/L), although faster flows contain a short‐lived initial period of coarser‐grained or higher‐concentration flow within a few meters of the bed. The body of these flows tends toward a maximum speed of 0.8–1 m/s, which may indicate an equilibrium in which flow speeds suspend available sediment. Average sediment concentration and flow thickness determine the gravitational driving force, which we then compared to average velocities. This comparison suggests surprisingly low friction values, comparable to or less than those of major rivers. This new approach therefore provides fundamental insights into one of the major sediment transport processes on Earth.

Published
2020

7. Interactions between sediment microbial ecology and physical dynamics drive heterogeneity in contextually similar depositional systems

Author

Hope, J. A., Malarkey, J., Baas, J. H., Peakall, J., Parsons, D. R., Manning, A. J., Bass, S. J., Lichtman, I. D., Thorne, P. D., Ye, L., Paterson, D. M., Hope, J. A., Malarkey, J., Baas, J. H., Peakall, J., Parsons, D. R., Manning, A. J., Bass, S. J., Lichtman, I. D., Thorne, P. D., Ye, L., and Paterson, D. M.

Abstract

This study focuses on the interactions between sediment stability and biological and physical variables that influence the erodibility across different habitats. Sampling at short‐term temporal scales illustrated the persistence of the microphytobenthos (MPB) biomass even during periods of frequent, high physical disturbance. The role of MPB in biological stabilization along the changing sedimentary habitat was also assessed. Key biological and physical properties, such as the MPB biomass, composition, and extracellular polymeric substances, were used to predict the sediment stability (erosion threshold) of muddy and sandy habitats within close proximity to one another over multiple days, and within emersion periods. The effects of dewatering, MPB growth, and productivity were examined as well as the resilience and recovery of the MPB community after disturbance from tidal currents and waves. Canonical analysis of principal components (CAP) ordinations were used to visualize and assess the trends observed in biophysical properties between the sites, and marginal and sequential distance‐based linear models were used to identify the key properties influencing erodibility. While the particle size of the bed was important for differences between sites in the CAP analysis, it contributed less to the variability in sediment erodibility than key biological parameters. Among the biological predictors, MPB diversity explained very little variation in marginal tests but was a significant predictor in sequential tests when MPB biomass was also considered. MPB diversity and biomass were both key predictors of sediment stability, contributing 9% and 10%, respectively, to the final model compared to 2% explained by grain size.

Published
2020

8. Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits

Author

Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., Talling, P. J., Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., and Talling, P. J.

Abstract

Burial of terrestrial biospheric particulate organic carbon in marine sediments removes CO2 from the atmosphere, regulating climate over geologic time scales. Rivers deliver terrestrial organic carbon to the sea, while turbidity currents transport river sediment further offshore. Previous studies have suggested that most organic carbon resides in muddy marine sediment. However, turbidity currents can carry a significant component of coarser sediment, which is commonly assumed to be organic carbon poor. Here, using data from a Canadian fjord, we show that young woody debris can be rapidly buried in sandy layers of turbidity current deposits (turbidites). These layers have organic carbon contents 10x higher than the overlying mud layer, and overall, woody debris makes up >70% of the organic carbon preserved in the deposits. Burial of woody debris in sands overlain by mud caps reduces their exposure to oxygen, increasing organic carbon burial efficiency. Sandy turbidity current channels are common in fjords and the deep sea; hence we suggest that previous global organic carbon burial budgets may have been underestimated.

Published
2020
Full Text
View/download PDF

9. Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits

Author

Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., Talling, P. J., Hage, Sophie, Galy, V. V., Cartigny, M. J. B., Acikalin, S., Clare, M. A., Grocke, D. R., Hilton, R. G., Hunt, J. E., Lintern, D. G., Mcghee, C. A., Parsons, D. R., Stacey, C. D., Sumner, E. J., and Talling, P. J.

Abstract

Burial of terrestrial biospheric particulate organic carbon in marine sediments removes CO2 from the atmosphere, regulating climate over geologic time scales. Rivers deliver terrestrial organic carbon to the sea, while turbidity currents transport river sediment further offshore. Previous studies have suggested that most organic carbon resides in muddy marine sediment. However, turbidity currents can carry a significant component of coarser sediment, which is commonly assumed to be organic carbon poor. Here, using data from a Canadian fjord, we show that young woody debris can be rapidly buried in sandy layers of turbidity current deposits (turbidites). These layers have organic carbon contents 10x higher than the overlying mud layer, and overall, woody debris makes up >70% of the organic carbon preserved in the deposits. Burial of woody debris in sands overlain by mud caps reduces their exposure to oxygen, increasing organic carbon burial efficiency. Sandy turbidity current channels are common in fjords and the deep sea; hence we suggest that previous global organic carbon burial budgets may have been underestimated.

Published
2020
Full Text
View/download PDF

10. Interactions between sediment microbial ecology and physical dynamics drive heterogeneity in contextually similar depositional systems

Author

Hope, J. A., Malarkey, J., Baas, J. H., Peakall, J., Parsons, D. R., Manning, A. J., Bass, S. J., Lichtman, I. D., Thorne, P. D., Ye, L., Paterson, D. M., Hope, J. A., Malarkey, J., Baas, J. H., Peakall, J., Parsons, D. R., Manning, A. J., Bass, S. J., Lichtman, I. D., Thorne, P. D., Ye, L., and Paterson, D. M.

Abstract

This study focuses on the interactions between sediment stability and biological and physical variables that influence the erodibility across different habitats. Sampling at short‐term temporal scales illustrated the persistence of the microphytobenthos (MPB) biomass even during periods of frequent, high physical disturbance. The role of MPB in biological stabilization along the changing sedimentary habitat was also assessed. Key biological and physical properties, such as the MPB biomass, composition, and extracellular polymeric substances, were used to predict the sediment stability (erosion threshold) of muddy and sandy habitats within close proximity to one another over multiple days, and within emersion periods. The effects of dewatering, MPB growth, and productivity were examined as well as the resilience and recovery of the MPB community after disturbance from tidal currents and waves. Canonical analysis of principal components (CAP) ordinations were used to visualize and assess the trends observed in biophysical properties between the sites, and marginal and sequential distance‐based linear models were used to identify the key properties influencing erodibility. While the particle size of the bed was important for differences between sites in the CAP analysis, it contributed less to the variability in sediment erodibility than key biological parameters. Among the biological predictors, MPB diversity explained very little variation in marginal tests but was a significant predictor in sequential tests when MPB biomass was also considered. MPB diversity and biomass were both key predictors of sediment stability, contributing 9% and 10%, respectively, to the final model compared to 2% explained by grain size.

Published
2020

11. Novel acoustic method provides first detailed measurements of sediment concentration structure within submarine turbidity currents

Author

Simmons, S. M., Azpiroz‐Zabala, M., Cartigny, M. J .B., Clare, M. A., Cooper, C., Parsons, D. R., Pope, E. L., Sumner, E. J., Talling, P. J., Simmons, S. M., Azpiroz‐Zabala, M., Cartigny, M. J .B., Clare, M. A., Cooper, C., Parsons, D. R., Pope, E. L., Sumner, E. J., and Talling, P. J.

Abstract

Turbidity currents transport prodigious volumes of sediment to the deep sea. But there are very few direct measurements from oceanic turbidity currents, ensuring they are poorly understood. Recent studies have used acoustic Doppler current profilers (ADCPs) to measure velocity profiles of turbidity currents. However, there were no detailed measurements of sediment concentration, which is a critical parameter because it provides the driving force and debate centers on whether flows are dilute or dense. Here we provide the most detailed measurements yet of sediment concentration in turbidity currents via a new method using dual‐frequency acoustic backscatter ADCP data. Backscatter intensity depends on size and concentration of sediment, and we disentangle these effects. This approach is used to document the internal structure of turbidity currents in Congo Canyon. Flow duration is bimodal, and some flows last for 5–10 days. All flows are mainly dilute (<10 g/L), although faster flows contain a short‐lived initial period of coarser‐grained or higher‐concentration flow within a few meters of the bed. The body of these flows tends toward a maximum speed of 0.8–1 m/s, which may indicate an equilibrium in which flow speeds suspend available sediment. Average sediment concentration and flow thickness determine the gravitational driving force, which we then compared to average velocities. This comparison suggests surprisingly low friction values, comparable to or less than those of major rivers. This new approach therefore provides fundamental insights into one of the major sediment transport processes on Earth.

Published
2020

12. Novel Acoustic Method Provides First Detailed Measurements of Sediment Concentration Structure Within Submarine Turbidity Currents

Author

Simmons, S. M. (author), Azpiroz Zabala, M. (author), Cartigny, M. J.B. (author), Clare, M. A. (author), Cooper, C. (author), Parsons, D. R. (author), Pope, E. L. (author), Sumner, E. J. (author), Talling, P. J. (author), Simmons, S. M. (author), Azpiroz Zabala, M. (author), Cartigny, M. J.B. (author), Clare, M. A. (author), Cooper, C. (author), Parsons, D. R. (author), Pope, E. L. (author), Sumner, E. J. (author), and Talling, P. J. (author)

Abstract

Turbidity currents transport prodigious volumes of sediment to the deep sea. But there are very few direct measurements from oceanic turbidity currents, ensuring they are poorly understood. Recent studies have used acoustic Doppler current profilers (ADCPs) to measure velocity profiles of turbidity currents. However, there were no detailed measurements of sediment concentration, which is a critical parameter because it provides the driving force and debate centers on whether flows are dilute or dense. Here we provide the most detailed measurements yet of sediment concentration in turbidity currents via a new method using dual-frequency acoustic backscatter ADCP data. Backscatter intensity depends on size and concentration of sediment, and we disentangle these effects. This approach is used to document the internal structure of turbidity currents in Congo Canyon. Flow duration is bimodal, and some flows last for 5–10 days. All flows are mainly dilute (<10 g/L), although faster flows contain a short-lived initial period of coarser-grained or higher-concentration flow within a few meters of the bed. The body of these flows tends toward a maximum speed of 0.8–1 m/s, which may indicate an equilibrium in which flow speeds suspend available sediment. Average sediment concentration and flow thickness determine the gravitational driving force, which we then compared to average velocities. This comparison suggests surprisingly low friction values, comparable to or less than those of major rivers. This new approach therefore provides fundamental insights into one of the major sediment transport processes on Earth., Applied Geology

Published
2020
Full Text
View/download PDF

13. Self-sharpening induces jet-like structure in seafloor gravity currents

Author

Dorrell, R. M., Peakall, J., Darby, S. E., Parsons, D. R., Johnson, J., Sumner, E. J., Wynn, R. B., Özsoy, E., Tezcan, D., Dorrell, R. M., Peakall, J., Darby, S. E., Parsons, D. R., Johnson, J., Sumner, E. J., Wynn, R. B., Özsoy, E., and Tezcan, D.

Abstract

Gravity currents are the primary means by which sediments, solutes and heat are transported across the ocean-floor. Existing theory of gravity current flow employs a statistically-stable model of turbulent diffusion that has been extant since the 1960s. Here we present the first set of detailed spatial data from a gravity current over a rough seafloor that demonstrate that this existing paradigm is not universal. Specifically, in contrast to predictions from turbulent diffusion theory, self-sharpened velocity and concentration profiles and a stable barrier to mixing are observed. Our new observations are explained by statistically-unstable mixing and self-sharpening, by boundary-induced internal gravity waves; as predicted by recent advances in fluid dynamics. Self-sharpening helps explain phenomena such as ultra-long runout of gravity currents and restricted growth of bedforms, and highlights increased geohazard risk to marine infrastructure. These processes likely have broader application, for example to wave-turbulence interaction, and mixing processes in environmental flows.

Published
2019

14. The Impact of Nonequilibrium Flow on the Structure of Turbulence Over River Dunes

Author

Unsworth, C. A., Parsons, D. R., Hardy, R. J., Reesink, A. J. H., Best, J. L., Ashworth, P. J., Keevil, G. M., Unsworth, C. A., Parsons, D. R., Hardy, R. J., Reesink, A. J. H., Best, J. L., Ashworth, P. J., and Keevil, G. M.

Abstract

This piece of research expands our description of how rivers flow over dunes on a river bed. Most of the scientific communities' research to date has used unnaturally steady conditions to measure how water moves over dunes. Yet these flow conditions are not strictly true to the variety of conditions nature produces, most importantly during floods. This research is the first detailed description of a wide range of flow states over dunes and changes our present understanding of the structure of flow over dunes in rivers. Consequently, the scientific community will be able to use this new information to better model and simulate how rivers work, how they flood, and how they transport sediment toward the world's deltas.

Published
2018

15. The Impact of Nonequilibrium Flow on the Structure of Turbulence Over River Dunes

Author

Unsworth, C. A., Parsons, D. R., Hardy, R. J., Reesink, A. J. H., Best, J. L., Ashworth, P. J., Keevil, G. M., Unsworth, C. A., Parsons, D. R., Hardy, R. J., Reesink, A. J. H., Best, J. L., Ashworth, P. J., and Keevil, G. M.

Abstract

This piece of research expands our description of how rivers flow over dunes on a river bed. Most of the scientific communities' research to date has used unnaturally steady conditions to measure how water moves over dunes. Yet these flow conditions are not strictly true to the variety of conditions nature produces, most importantly during floods. This research is the first detailed description of a wide range of flow states over dunes and changes our present understanding of the structure of flow over dunes in rivers. Consequently, the scientific community will be able to use this new information to better model and simulate how rivers work, how they flood, and how they transport sediment toward the world's deltas.

Published
2018

16. Groundwater seepage landscapes from distant and local sources in experiments and on Mars

Author

Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., Kleinhans, M. G., Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., and Kleinhans, M. G.

Abstract

Valleys with theater-shaped heads can form due to the seepage of groundwater and as a result of knickpoint (waterfall) erosion generated by overland flow. This ambiguity in the mechanism of formation hampers the interpretation of such valleys on Mars, particularly since there is limited knowledge of material properties. Moreover, the hydrological implications of a groundwater or surface water origin are important for our understanding of the evolution of surface features on Mars, and a quantification of valley morphologies at the landscape scale may provide diagnostic insights on the formative hydrological conditions. However, flow patterns and the resulting landscapes produced by different sources of groundwater are poorly understood. We aim to improve the understanding of the formation of entire valley landscapes through seepage processes from different groundwater sources that will provide a framework of landscape metrics for the interpretation of such systems. We study groundwater seepage from a distant source of groundwater and from infiltration of local precipitation in a series of sandbox experiments and combine our results with previous experiments and observations of the Martian surface. Key results are that groundwater flow piracy acts on valleys fed by a distant groundwater source and results in a sparsely dissected landscape of many small and a few large valleys. In contrast, valleys fed by a local groundwater source, i.e., nearby infiltration, result in a densely dissected landscape. In addition, valleys fed by a distant groundwater source grow towards that source, while valleys with a local source grow in a broad range of directions and have a strong tendency to bifurcate, particularly on flatter surfaces. We consider these results with respect to two Martian cases: Louros Valles shows properties of seepage by a local source of groundwater and Nirgal Vallis shows evidence of a distant source, which we interpret as groundwater flow from Tharsis.

Published
2015

17. Groundwater seepage landscapes from distant and local sources in experiments and on Mars

Author

Geomorfologie, Coastal dynamics, Fluvial systems and Global change, Landscape functioning, Geocomputation and Hydrology, Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., Kleinhans, M. G., Geomorfologie, Coastal dynamics, Fluvial systems and Global change, Landscape functioning, Geocomputation and Hydrology, Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., and Kleinhans, M. G.

Published
2015

18. Groundwater seepage landscapes from distant and local sources in experiments and on Mars

Author

Geomorfologie, Coastal dynamics, Fluvial systems and Global change, Landscape functioning, Geocomputation and Hydrology, Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., Kleinhans, M. G., Geomorfologie, Coastal dynamics, Fluvial systems and Global change, Landscape functioning, Geocomputation and Hydrology, Marra, W. A., McLelland, S. J., Parsons, D. R., Murphy, B. J., Hauber, E., and Kleinhans, M. G.

Published
2015

23. An Endangered Species Survey of Abandoned Mine Shafts in the Big South Fork National River and Recreation Area, Kentucky and Tennessee.

Author

FISH AND WILDLIFE SERVICE COOKEVILLE TN ECOLOGICAL SERVICES OFFICE, Barclay,L A , Jr, Parsons,D R, FISH AND WILDLIFE SERVICE COOKEVILLE TN ECOLOGICAL SERVICES OFFICE, Barclay,L A , Jr, and Parsons,D R

Abstract

A total of 114 abandoned mine openings in the Big South Fork National River and Recreation Area (BSFNRRA) was surveyed for the presence of endangered species of bats between December 10, 1982, and April 14, 1983. Although no endangered species were found, 351 bats representing 6 species were encountered using these mines. Species encountered include eastern pipistrelle, Rafinesque's big-eared bat, big brown bat, Keen's bat, little brown bat, and small-footed bat. Suitability of mines as bat habitat, accounts of bat species encountered, life history requisites of endangered Indiana and gray bats, methods of closing abandoned mine openings, protecting bat habitat and the public, and other management considerations are discussed. Alternatives for treatment of abandoned mine openings in the BSFNRRA are presented.

Published
1983

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