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  • 1
    Online Resource
    Online Resource
    Fluvial-Tidal Sedimentology. (2015)
    San Diego :Elsevier,
    Details
    Keywords: Sediment transport. ; Electronic books.
    Type of Medium: Online Resource
    Pages: 1 online resource (719 pages)
    Edition: 1st ed.
    ISBN: 9780444635396
    Series Statement: Issn Series ; v.Volume 68
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=4179310
    DDC: 551.3
    Language: English
    Note: Front Cover -- Fluvial-Tidal Sedimentology -- Copyright -- Contents -- Contributors -- Preface -- Part 1: Context -- Chapter 1: Deciphering the relative importance of fluvial and tidal processes in the fluvial-marine transition -- 1.1. Introduction -- 1.2. Process Framework for the Fluvial-Tidal Transition -- 1.3. Setting of the Case Studies Used in This Chapter -- 1.3.1. Lajas Formation, Neuquén Basin, Argentina -- 1.3.2. McMurray Formation, Northern Alberta -- 1.3.3. Neslen Formation, Book Cliffs, Utah -- 1.3.4. Tilje Formation, Offshore Norway -- 1.3.5. Bluesky Formation, Peace River Area, Alberta -- 1.4. Description and Interpretation of the Case Studies -- 1.4.1. Case Study1: Lower Lajas Formation -- 1.4.2. Case Study2: McMurray Formation -- 1.4.3. Case Study3: Middle Lajas Formation -- 1.4.4. Case Study4: Middle Neslen Formation -- 1.4.5. Case Study5: Middle Neslen Formation -- 1.4.6. Case Study6: Tilje Formation -- 1.4.7. Case Study7: Bluesky Formation -- 1.5. Discussion -- 1.6. Conclusions -- Acknowledgments -- References -- Part 2: Modern -- Chapter 2: Estuarine turbidity maxima revisited: Instrumental approaches, remote sensing, modeling studies, and new direction -- 2.1. Introduction -- 2.1.1. Purpose: Toward a New Understanding -- 2.1.2. What Is an ETM and Why Does It Matter? -- 2.1.3. Scope of Paper -- 2.2. In Situ Measurements: Recent Advances -- 2.2.1. Acoustical Measurements and Instruments -- 2.2.1.1. Uses of the Acoustic Doppler Velocimeter -- 2.2.1.2. ADCP methods -- 2.2.1.3. Other acoustic methods -- 2.2.2. Optical Measurements and Instruments -- 2.2.2.1. Optical backscatter sensors -- 2.2.2.2. The laser in situ scattering transmissometer -- 2.2.2.3. Holography and floc cameras -- 2.2.2.4. Inherent optical property measurements and theoretical modeling of particle optics. , 2.3. Building an Integral Understanding of ETM via Remote Sensing: Possibilities and Challenges -- 2.3.1. Measuring Turbidity Remotely -- 2.3.2. Lessons Learned from Remote Measurements in Estuaries -- 2.4. ETM Dynamic: Insights from Theory, Modeling and Observations -- 2.4.1. Estuarine Circulation and ETM Formation -- 2.4.2. The Traditional Model -- 2.4.3. More Complex Models -- 2.4.4. Integral Analysis of a Channelized ETM -- 2.5. Discussion: Toward a More Complete Understanding of ETM Dynamics -- 2.5.1. Making Use of New In Situ and Remote Sensing Capabilities -- 2.5.2. Dynamical Questions -- 2.5.2.1. Trapping mechanisms and the material trapped -- 2.5.2.2. Nonstationary aspects of ETM -- 2.5.2.3. Distinguishing human and climatic impacts on ETM dynamics and ecosystems -- 2.5.2.4. ETM dynamics and contaminants -- 2.6. Summary and Conclusions -- Acknowledgments -- References -- Chapter 3: Sedimentological trends across the tidal-fluvial transition, Fraser River, Canada: A review and some broader impli -- 3.1. Introduction -- 3.1.1. Fraser River, Canada -- 3.2. Depositional Trends Across the TFT of the Fraser River -- 3.2.1. Sedimentological Trends -- 3.2.2. Ichnological Trends -- 3.2.3. Palynological and Geochemical Trends -- 3.3. The Broader Implications of Depositional Trends from the Lower Fraser River -- 3.3.1. Expected Variations in Depositional Trends -- 3.4. Conclusions -- References -- Chapter 4: Three-dimensional meander bend flow within the tidally influenced fluvial zone -- 4.1. Introduction -- 4.2. Methods -- 4.2.1. Field Area -- 4.2.2. Field Methods -- 4.3. Results -- 4.3.1. High River-Neap Tide -- 4.3.2. Low River-Spring Tide -- 4.3.3. Repeated Bend Apex Measurements at LRST -- 4.4. Discussion -- 4.5. Conclusions -- References. , Chapter 5: Sedimentology of a tidal point-bar within the fluvial-tidal transition: River Severn Estuary, UK -- 5.1. Introduction -- 5.2. Severn Estuary -- 5.2.1. Sampling Sites -- 5.3. Methods -- 5.3.1. Stratigraphic Descriptions -- 5.3.1.1. Pollen descriptions -- 5.4. Results -- 5.4.1. Sedimentary Facies -- 5.4.1.1. F1: Red mudstone -- 5.4.1.2. F2: Blue clay facies -- 5.4.1.3. F3: Poorly sorted coarse sand and gravel facies -- 5.4.1.4. F4: Homogeneous sand facies -- 5.4.1.5. F5: Heterolithic facies -- 5.4.1.6. F6: Orange-brown silty-mud facies -- 5.4.1.7. F7: Gray-dark organic matter stratification in a mud matrix facies -- 5.4.1.8. F8: Gray-brown marsh facies -- 5.4.2. Summary of Facies Assemblages -- 5.4.3. Distinctiveness of the Transitional Facies Assemblage -- 5.4.3.1. The first unit is the marsh (F8) facies -- 5.4.3.2. The second unit is the heterolithic facies (F5) -- 5.4.3.3. The third unit is constituted of fine to coarse sand (F3+F4) -- 5.4.3.4. Box tray samples of Rodley sand bar -- 5.4.4. Pollen -- 5.4.4.1. Fluvial (Core 4) -- 5.4.4.2. Transition (Core 5) -- 5.4.4.3. Marine (Core 7) -- 5.4.4.4. Detrended correspondence analysis -- 5.4.5. Diatoms -- 5.4.5.1. Fluvial (Core 4) -- 5.4.5.2. Transitional (Core 5) -- 5.4.5.3. Marine (Core 7) -- 5.5. Discussion -- 5.5.1. Allogenic Processes -- 5.5.2. Autogenic Processes -- 5.5.3. Model of Deposition -- 5.6. Conclusions -- Acknowledgments -- References -- Part 3: Ancient -- Chapter 6: Mid to late Holocene geomorphological and sedimentological evolution of the fluvial-tidal zone: Lower Columbia Riv -- 6.1. Introduction -- 6.2. Background -- 6.2.1. LCR: Geological Setting and Study Reach -- 6.3. Methodologies -- 6.3.1. Sediment Core Collection and OSL Sampling -- 6.3.2. OSL Laboratory Analysis -- 6.4. Results -- 6.4.1. Mid-Holocene to Present Depositional Patterns. , 6.4.2. LCR Depositional Patterns: 4.3-2.0ka -- 6.4.3. LCR Depositional Patterns: 2.0-1.0ka -- 6.4.4. LCR Depositional Patterns: 1.0ka to Present -- 6.5. Discussion -- 6.5.1. LCR Mid to Late Holocene Depositional Setting: "Bay-Head Delta" Hypothesis? -- 6.5.2. LCR Mid to Late Holocene Geomorphic/Sedimentological Model -- 6.6. Conclusions -- Acknowledgments -- References -- Chapter 7: Palaeo-Orinoco (Pliocene) channels on the tide-dominated Morne L'Enfer delta lobes and estuaries, SW Trinidad -- 7.1. Introduction -- 7.2. Geological Background -- 7.2.1. Regional Tectonic and Stratigraphic Setting -- 7.2.2. Methodology and Data Sets -- 7.2.3. Architecture of Deltaic and Estuarine Units in the MLE Succession -- 7.3. Palaeo-Orinoco Context of Tidal-Fluvial Channels -- 7.4. Criteria for the Recognition of Tidal Signals in and Around the Channels -- 7.4.1. Fluid mud Layers -- 7.4.2. Palaeoflow Indicators: Bidirectional Ripples -- 7.4.3. Cross-Strata -- 7.4.4. Tidal Rhythmites -- 7.4.4.1. Rhythmites with tidal bundling from asymmetric tidal cycles (with double mud drapes) -- 7.4.4.2. Tidal bundling from a series of spring-neap tides -- 7.4.5. Flaser (Frequent Mud Drapes), Wavy, Lenticular, and "Pin-Stripe" Bedding -- 7.5. Examples of Palaeo-Orinoco Tidal-Fluvial Channels -- 7.5.1. Regressive Channels (Delta Plain and Delta-Front Distributary Channels) -- 7.5.1.1. Fluvial-tidal distributary channels on delta plain or entering embayment -- 7.5.1.2. Fluvial-tidal distributary channels cutting down onto the delta front -- 7.5.2. Transgressive Estuarine Channels -- 7.5.2.1. Transgressive inner estuarine channel -- 7.5.2.2. Transgressive outer estuarine channel -- 7.5.3. Facies Comparison Between Regressive and Transgressive Tidal Channels -- 7.6. Discussion -- 7.7. Conclusions -- Acknowledgments -- References. , Chapter 8: The ichnology of the fluvial-tidal transition: Interplay of ecologic and evolutionary controls -- 8.1. Introduction -- 8.2. Ecologic Controls on the Ichnofauna at the Fluvial-Tidal Zone: Insights from Neoichnology -- 8.3. Case Studies -- 8.3.1. Carboniferous of Kansas (Tonganoxie Sandstone Member) -- 8.3.2. Upper Carboniferous of Nova Scotia (Coal Mine Point Channel Body) -- 8.3.3. Upper Carboniferous of Alabama (Mary Lee Coal Zone) -- 8.3.4. Upper Carboniferous of Indiana (Mansfield Formation) -- 8.3.5. Lower Permian of New Mexico (Robledo Mountains Formation) -- 8.3.6. Upper Cretaceous of Spain (Tremp Formation) -- 8.3.7. Lower Oligocene to lower Miocene of Venezuela (Guafita Formation) -- 8.3.8. Lower Miocene of Venezuela (Oficina Formation) -- 8.3.9. Lower Miocene of Northern Brazil (Barreiras Formation) -- 8.3.10. Upper Miocene of Western Brazil (Solimões Formation) -- 8.4. Summary of Observations and Discussion: Ecologic and Evolutionary Controls -- 8.4.1. Ecologic Controls -- 8.4.2. Evolutionary Controls -- 8.5. Conclusions -- Acknowledgments -- References -- Chapter 9: A reappraisal of large, heterolithic channel fills in the upper Permian Rangal Coal Measures of the Bowen Basin, Q -- 9.1. Introduction -- 9.2. Geological Setting -- 9.3. Previous Research -- 9.4. Facies Analysis -- 9.5. Evidence for Tidal Influence -- 9.5.1. Stratigraphic Context -- 9.5.2. Inclined Heterolithic Stratification -- 9.5.3. Small-Scale Sedimentary Structures and Trace Fossils -- 9.5.4. Palaeocurrent Data -- 9.5.5. Fossil Fish -- 9.6. Discussion -- 9.7. Conclusions -- Acknowledgments -- References -- Chapter 10: Facies and architecture of unusual fluvial-tidal channels with inclined heterolithic strata: Campanian Neslen For -- 10.1. Introduction -- 10.2. Regional Geology and Previous Work. , 10.2.1. Neslen and Sego/Corcoran/Cozette Deposits as a Low-Accommodation Interval.
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  • 2
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    Organic carbon measurements on Bute Inlet river samples (2022)
    PANGAEA
    Details
    Publication Date: 2023-02-07
    Description: This dataset includes organic carbon measurements on sediment samples collected in Bute Inlet (British Columbia, Canada) in October 2016 (cruise number PGC2016007) and October 2017 (cruise number PGC2017005) aboard the research vessel CCGS Vector. The cruise PGC2016007 took place between 7 October and 17 October 2016 and was led by Gwyn Lintern. The cruise PGC2017005 took place between 19 and 29 October and was led by Cooper Stacey. River samples were taken in the Homathko and Southgate rivers using Niskin bottles in the water column and a grab sampler in the river beds and the river deltas
    Keywords: Age, 14C AMS; Age, dated; Bottle, Niskin; Bute Inlet, British Columbia, Canada; Carbon, organic, total; DEPTH, sediment/rock; DEPTH, water; Environment; Event label; fjords; Grab; GRAB; Latitude of event; Longitude of event; NIS; organic carbon (OC); Percentile 50; Percentile 90; PGC-2017-005; PGC-2017-005_RB16; PGC-2017-005_RB22; PGC-2017-005_RB24; PGC-2017-005_RBL18; PGC-2017-005_RD12; PGC-2017-005_RD14; PGC-2017-005_RD6; PGC-2017-005_RD8; PGC-2017-005_RP11; PGC-2017-005_RP13; PGC-2017-005_RP15; PGC-2017-005_RP16; PGC-2017-005_RP17; PGC-2017-005_RP19; PGC-2017-005_RP7; PGC-2017-005_RP9; PGC-2017-005_RW23; PGC-2017-005_SS18; PGC-2017-005_SS20; River; sediment; submarine canyon; Vector; δ13C, organic carbon
    Type: Dataset
    Format: text/tab-separated-values, 118 data points
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    DATA PANGAEA
  • 3
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    Organic carbon measurements on Bute Inlet marine sediment samples (2022)
    PANGAEA
    Details
    Publication Date: 2023-02-07
    Description: This dataset includes organic carbon measurements on sediment samples collected in Bute Inlet (British Columbia, Canada) in October 2016 (cruise number PGC2016007) and October 2017 (cruise number PGC2017005) aboard the research vessel CCGS Vector. The cruise PGC2016007 took place between 7 October and 17 October 2016 and was led by Gwyn Lintern. The cruise PGC2017005 took place between 19 and 29 October and was led by Cooper Stacey. Marine sediment samples were collected in Bute Inlet using a box corer for the sandy samples in the submarine channel and a piston corer for the muddy samples in the overbanks and distal basin.
    Keywords: 1; 10; 11; 12; 13; 14; 15; 2; 3; 4; 5; 6; 7; 8; 9; Age, 14C AMS; Age, dated; BC; Box corer; Bute Inlet, British Columbia, Canada; Carbon, organic, total; Core; Depth, bottom/max; DEPTH, sediment/rock; Depth, top/min; Elevation of event; Event label; fjords; Latitude of event; Longitude of event; Method/Device of event; organic carbon (OC); PC; Percentile 50; Percentile 90; PGC-2016-003; PGC-2016-003_STN01; PGC-2016-007; PGC-2016-007_STN010; PGC-2016-007_STN014; PGC-2016-007_STN015; PGC-2016-007_STN019; PGC-2016-007_STN020; PGC-2016-007_STN021; PGC-2016-007_STN025; PGC-2016-007_STN026; PGC-2016-007_STN028; PGC-2016-007_STN029; PGC-2016-007_STN030; PGC-2016-007_STN031; PGC-2016-007_STN032; PGC-2016-007_STN036; PGC-2016-007_STN09; Piston corer; sediment; Sub-Environment; submarine canyon; Vector; δ13C, organic carbon
    Type: Dataset
    Format: text/tab-separated-values, 516 data points
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    DATA PANGAEA
  • 4
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    Seawater carbonate chemistry and fish hearing (2021)
    PANGAEA
    Details
    Publication Date: 2024-03-15
    Description: Humans are rapidly changing the marine environment through a multitude of effects, including increased greenhouse gas emissions resulting in warmer and acidified oceans. Elevated CO2 conditions can cause sensory deficits and altered behaviours in marine organisms, either directly by affecting end organ sensitivity or due to likely alterations in brain chemistry. Previous studies show that auditory-associated behaviours of larval and juvenile fishes can be affected by elevated CO2 (1000 µatm). Here, using auditory evoked potentials (AEP) and micro-computer tomography (microCT) we show that raising juvenile snapper, Chrysophyrs auratus, under predicted future CO2 conditions resulted in significant changes to their hearing ability. Specifically, snapper raised under elevated CO2 conditions had a significant decrease in low frequency (less than 200 Hz) hearing sensitivity. MicroCT demonstrated that these elevated CO2 snapper had sacculus otolith's that were significantly larger and had fluctuating asymmetry, which likely explains the difference in hearing sensitivity. We suggest that elevated CO2 conditions have a dual effect on hearing, directly effecting the sensitivity of the hearing end organs and altering previously described hearing induced behaviours. This is the first time that predicted future CO2 conditions have been empirically linked through modification of auditory anatomy to changes in fish hearing ability. Given the widespread and well-documented impact of elevated CO2 on fish auditory anatomy, predictions of how fish life-history functions dependent on hearing may respond to climate change may need to be reassessed.
    Keywords: Alkalinity, total; Alkalinity, total, standard deviation; Animalia; Aragonite saturation state; Aragonite saturation state, standard deviation; Bicarbonate ion; Bicarbonate ion, standard deviation; Calcite saturation state; Calcite saturation state, standard deviation; Calculated using CO2SYS; Calculated using seacarb after Nisumaa et al. (2010); Calculated using seacarb after Orr et al. (2018); Carbon, inorganic, dissolved; Carbon, inorganic, dissolved, standard deviation; Carbonate ion; Carbonate ion, standard deviation; Carbonate system computation flag; Carbon dioxide; Carbon dioxide, standard deviation; Chordata; Chrysophyrs auratus; Coast and continental shelf; Containers and aquaria (20-1000 L or 〈 1 m**2); Diameter; Frequency; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Fugacity of carbon dioxide in seawater, standard deviation; Growth/Morphology; Identification; Laboratory experiment; Length; Nekton; OA-ICC; Ocean Acidification International Coordination Centre; Other studied parameter or process; Partial pressure of carbon dioxide, standard deviation; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); Pelagos; Perimeter; pH; pH, standard deviation; Potentiometric titration; Pressure sensitivity; Registration number of species; Salinity; Salinity, standard deviation; Side; Single species; South Pacific; Species; Spectrophotometric; Surface area; Temperate; Temperature, water; Temperature, water, standard deviation; Treatment; Type; Uniform resource locator/link to reference; Volume
    Type: Dataset
    Format: text/tab-separated-values, 6284 data points
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    DATA PANGAEA
  • 5
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    Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits (2020)
    Hage, S., 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. (2020). Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits. Geology, 48(9), 882-887.
    Details
    Publication Date: 2022-10-05
    Description: © The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Hage, S., 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. Efficient preservation of young terrestrial organic carbon in sandy turbidity-current deposits. Geology, 48(9), (2020): 882-887, doi:10.1130/G47320.1.
    Description: 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 10× 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.
    Description: We thank C. Johnson, M. Lardie, A. Gagnon, A. McNichol, and the NOSAMS (National Ocean Sciences Accelerator Mass Spectrometry) team (Woods Hole Oceanographic Institution [WHOI], Massachusetts, USA) for their help with ramped oxidation system and isotopes. We thank the captain and crew of CCGS Vector. Support was provided by UK Natural Environment Research Council (NERC) grants NE/M007138/1 (to Cartigny) and NE/L013142/1 (to Talling), NE/P005780/1 and NE/P009190/1 (to Clare); a Royal Society Research Fellowship (to Cartigny); an International Association of Sedimentologists Postgraduate Grant and National Oceanography Centre Southampton–WHOI exchange program funds (to Hage); an independent study award from WHOI (to Galy); the Climate Linked Atlantic Sector Science (CLASS) program (NERC grant NE/R015953/1); and the European Research Council under the European Union’s Horizon 2020 research and innovation program (Grant 725955, to Parsons). We thank François Baudin, Xingqian Cui, editor James Schmitt, and three anonymous reviewers.
    Repository Name: Woods Hole Open Access Server
    Type: Article
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  • 6
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    Turbidity currents can dictate organic carbon fluxes across river‐fed fjords: an example from Bute Inlet (BC, Canada) (2022)
    American Geophysical Union
    Details
    Publication Date: 2022-10-26
    Description: © The Author(s), 2022. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Hage, S., Galy, V., Cartigny, M., Heerema, C., Heijnen, M., Acikalin, S., Clare, M., Giesbrecht, I., Gröcke, D., Hendry, A., Hilton, R., Hubbard, S., Hunt, J., Lintern, D., McGhee, C., Parsons, D., Pope, E., Stacey, C., Sumner, E., Tank, S., & Talling, P. Turbidity currents can dictate organic carbon fluxes across river‐fed fjords: an example from Bute Inlet (BC, Canada). Journal of Geophysical Research: Biogeosciences, 127(6), (2022): e2022JG006824, https://doi.org/10.1029/2022jg006824.
    Description: 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.
    Description: S.H. acknowledges funding by the IAS postgraduate grant scheme, a Research Development funds offered by Durham University, and the NOCS/WHOI exchange program. S.H. has received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant agreement no. 899546. The field campaign and geochemical analyses were supported by Natural Environment Research Council grants NE/M007138/1, NE/W30601/1, NE/N012798/1, NE/K011480/1 and NE/M017540/1. M.J.B.C. was funded by a Royal Society Research Fellowship (DHF\R1\180166). M.A.C. was supported by the U.K. National Capability NERC CLASS program (NE/R015953/1) and NERC grants (NE/P009190/1 and NE/P005780/1). C.J.H. and M.S.H. were funded by the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement no. 721403 - ITN SLATE. E.L.P. was supported by a Leverhulme Early Career Fellowship (ECF-2018-267).
    Keywords: Fjords ; Organic carbon ; Sediment ; Submarine channel ; Carbon burial ; Rivers
    Repository Name: Woods Hole Open Access Server
    Type: Article
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  • 7
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    Carbon and sediment fluxes inhibited in the submarine Congo Canyon by landslide-damming (2022)
    Nature Research
    Details
    Publication Date: 2024-02-07
    Description: Landslide-dams, which are often transient, can strongly affect the geomorphology, and sediment and geochemical fluxes, within subaerial fluvial systems. The potential occurrence and impact of analogous landslide-dams in submarine canyons has, however, been difficult to determine due to a scarcity of sufficiently time-resolved observations. Here we present repeat bathymetric surveys of a major submarine canyon, the Congo Canyon, offshore West Africa, from 2005 and 2019. We show how an ~0.09 km3 canyon-flank landslide dammed the canyon, causing temporary storage of a further ~0.4 km3 of sediment, containing ~5 Mt of primarily terrestrial organic carbon. The trapped sediment was up to 150 m thick and extended 〉26 km up-canyon of the landslide-dam. This sediment has been transported by turbidity currents whose sediment load is trapped by the landslide-dam. Our results suggest canyon-flank collapses can be important controls on canyon morphology as they can generate or contribute to the formation of meander cut-offs, knickpoints and terraces. Flank collapses have the potential to modulate sediment and geochemical fluxes to the deep sea and may impact efficiency of major submarine canyons as transport conduits and locations of organic carbon sequestration. This has potential consequences for deep-sea ecosystems that rely on organic carbon transported through submarine canyons.
    Type: Article , PeerReviewed
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 8
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    Longest sediment flows yet measured show how major rivers connect efficiently to deep sea (2022)
    Nature Research
    Details
    Publication Date: 2024-02-07
    Description: Here we show how major rivers can efficiently connect to the deep-sea, by analysing the longest runout sediment flows (of any type) yet measured in action on Earth. These seafloor turbidity currents originated from the Congo River-mouth, with one flow travelling 〉1,130 km whilst accelerating from 5.2 to 8.0 m/s. In one year, these turbidity currents eroded 1,338-2,675 [〉535-1,070] Mt of sediment from one submarine canyon, equivalent to 19–37 [〉7–15] % of annual suspended sediment flux from present-day rivers. It was known earthquakes trigger canyon-flushing flows. We show river-floods also generate canyon-flushing flows, primed by rapid sediment-accumulation at the river-mouth, and sometimes triggered by spring tides weeks to months post-flood. It is demonstrated that strongly erosional turbidity currents self-accelerate, thereby travelling much further, validating a long-proposed theory. These observations explain highly-efficient organic carbon transfer, and have important implications for hazards to seabed cables, or deep-sea impacts of terrestrial climate change.
    Type: Article , PeerReviewed
    Format: text
    Format: text
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 9
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    An Approach to the Core of Lactonamycin (2017)
    American Chemical Society (ACS)
    Details
    Publication Date: 2017-04-28
    Description: Organic Letters DOI: 10.1021/acs.orglett.7b00902
    Print ISSN: 1523-7060
    Electronic ISSN: 1523-7052
    Topics: Chemistry and Pharmacology
    Published by American Chemical Society (ACS)
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    PAPER CURRENT
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