Your search keyword '"Emily Eidam"' showing total 14 results

1. Impacts of 150 Years of Shoreline and Bathymetric Change in the Coos Estuary, Oregon, USA

Author

David A. Sutherland, J. Wood, Emily Eidam, Peter Ruggiero, J. Schmitt, Ted Conroy, David K. Ralston, and B. Dye

Subjects

0106 biological sciences, Shore, Hypsometry, geography, geography.geographical_feature_category, Tidal range, 010504 meteorology & atmospheric sciences, Ecology, 010604 marine biology & hydrobiology, Intertidal zone, Estuary, Aquatic Science, 01 natural sciences, Dredging, Oceanography, Environmental science, Bathymetry, Coastal management, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Estuaries worldwide have evolved over the past few centuries under development activities like dredging and shoreline reclamation, which commonly lead to increased channel depths and reduced intertidal areas. The Coos Estuary offers a useful example of how these changes, common to diverse global estuaries, have altered tidal and salt dynamics, with implications for estuarine habitats. In the past 150 years, the primary navigation channel has been deepened from ~ 6.7 to 11 m, generating a 12% decrease in estuary area and 21% increase in volume. To evaluate the present and future impacts on the Coos and similar estuaries, a hydrodynamic model was implemented using a detailed bathymetric dataset compiled from multiple data sources including agency charts, water-penetrating lidar, and single-beam-sonar small-vessel surveys. The model was then re-run using grids constructed from 1865 survey data and a future proposed dredging plan. Changes in the hypsometry from 1865 to present have driven a 33% increase in tidal amplitude, an 18% increase in salinity intrusion length, a doubling of the subtidal salt flux, and an increase in ebb dominance of currents. A proposed channel-depth increase from 11 to 14 m is predicted to generate a negligible change in tidal range and a small increase in the salinity intrusion length. These results highlight the utility of curating high-resolution bathymetric datasets for coastal management applications through modeling. The historical and modern models quantify how local bathymetric modifications can significantly alter tidal and salinity regimes and provide context for estuarine response to global climate-change drivers.

Published

2020

2. Landfast ice and coastal wave exposure in northern Alaska

Author

Jim Thomson, Gleb Panteleev, Emily Eidam, Lucia Hosekova, W. Erick Rogers, and Luc Rainville

Subjects

geography, Geophysics, Oceanography, geography.geographical_feature_category, Arctic, Surface wave, Sea ice, Strong coupling, General Earth and Planetary Sciences, Cover (algebra), Geology, Coastal erosion

Abstract

Observations of ocean surface waves at three sites along the northern coast of Alaska show a strong coupling with seasonal sea ice patterns. In the winter, ice cover is complete, and waves are abse...

Published

2021

3. Variability of Sediment Accumulation Rates in an Antarctic Fjord

Author

Øyvind Lundesgaard, Craig R. Smith, Emily Eidam, Charles A. Nittrouer, and K.K. Homolka

Subjects

geography, Geophysics, Oceanography, geography.geographical_feature_category, Tidewater glacier cycle, General Earth and Planetary Sciences, Sediment, Fjord, Geology

Published

2019

4. Shifting Sediment Dynamics in the Coos Bay Estuary in Response to 150 Years of Modification

Author

David A. Sutherland, David K. Ralston, T. Conroy, B. Dye, and Emily Eidam

Subjects

geography, geography.geographical_feature_category, Sediment, Estuary, Estuarine turbidity maximum, Oceanography, Dredging, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Bay

Published

2021

5. Attenuation of Ocean Surface Waves in Pancake and Frazil Sea Ice Along the Coast of the Chukchi Sea

Author

Luc Rainville, Lucia Hosekova, Emily Eidam, Mika Malila, Erick Rogers, Jim Thomson, Lettie A. Roach, and Nirnimesh Kumar

Subjects

geography, geography.geographical_feature_category, Oceanography, Mooring, Headland, Geophysics, Arctic, Space and Planetary Science, Geochemistry and Petrology, Surface wave, Wind wave, Earth and Planetary Sciences (miscellaneous), Sea ice, Significant wave height, Geology, Frazil ice

Abstract

Alaskan Arctic coastlines are protected seasonally from ocean waves by the presence of coastal and shorefast sea ice. This study presents field observations collected during the autumn 2019 freeze up near Icy Cape, a coastal headland in the Chukchi Sea of the Western Arctic. The evolution of the coupled air-ice-ocean-wave system during a four-day wave event was monitored using drifting wave buoys, a cross-shore mooring array, and ship-based measurements. The incident wave field with peak period of 2.5 s was attenuated by coastal pancake and frazil sea ice, reducing significant wave height by 40\% over less than 5 km of cross-shelf distance spanning water depths from 13 to 30 m. Spectral attenuation coefficients are evaluated with respect to wave and ice conditions and the proximity to the ice edge. Attenuation rates are found to be three times higher within 500 m of the ice edge, relative to values farther in the ice cover. Attenuation coefficients are in the range of $\langle 2.3,2.7\rangle$ \si{\meter^{-1}}, and follow a power-law dependence on frequency.

Published

2020

6. Morainal Bank Evolution and Impact on Terminus Dynamics During a Tidewater Glacier Stillstand

Author

Jason M. Amundson, Roman J. Motyka, David A. Sutherland, D. Duncan, Emily Eidam, and C. Kienholz

Subjects

geography, Geophysics, geography.geographical_feature_category, Oceanography, Moraine, Tidewater glacier cycle, Sediment, Fjord, Bathymetry, Geology, Earth-Surface Processes

Published

2020

7. The Mekong Continental Shelf: The Primary Sink for Deltaic Sediment Particles and Their Passengers

Author

Charles A. Nittrouer, Phach Phung, Emily Eidam, Andrea S. Ogston, T. T. Nguyen, Paul Liu, and David J. DeMaster

Subjects

geography, geography.geographical_feature_category, Oceanography, 010504 meteorology & atmospheric sciences, Continental shelf, 010502 geochemistry & geophysics, 01 natural sciences, Sink (geography), Geology, 0105 earth and related environmental sciences

Published

2017

8. A seismic study of the Mekong subaqueous delta: Proximal versus distal sediment accumulation

Author

Charles A. Nittrouer, Emily Eidam, T. T. Nguyen, David J. DeMaster, and J. Paul Liu

Subjects

Shore, Delta, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Continental shelf, Trough (geology), Fluvial, Geology, Aquatic Science, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Seafloor spreading, Peninsula, Facies, Geomorphology, 0105 earth and related environmental sciences

Abstract

The Mekong River Delta is one of the largest in Asia. To understand its sediment distribution, thickness, mass budget, stratigraphic sequences and sediment-transport process, extensive geophysical and geochemical surveys were conducted on the inner portions of the adjacent continental shelf. Analyses of > 80 high-resolution Chirp-sonar profiles show the Mekong River has formed a classic sigmoidal cross-shelf clinoform in the proximal areas, up to 15 m thick, with topset, foreset and bottomset facies, but constrained to water depths of 250 > 300 km southwestward to the tip of the Ca Mau Peninsula, forming a distal mud depocenter up to 22 m thick, and extending into the Gulf of Thailand. A large erosional trough or channel (up to 8 m deeper than the surrounding seafloor and parallel to the shore) was found on the top of the clinoform, east of the Ca Mau Peninsula. Based on the thicknesses and distribution revealed by Chirp sonar profiles, the total estimated volume of the Mekong River subaqueous clinoform on the shelf is ~120 km 3 , which is equivalent to ~120–140 × 10 9 t of sediment using an average sediment dry-bulk density of 1.0–1.2 g/cm 3 . Assuming the subaqueous deltaic deposit has formed within ~1000 yr, the calculated millennial-timescale average sediment discharge to the shelf could be 120–140 × 10 6 t per year. Spatially, the proximal subaqueous delta has accumulated ~45 × 10 9 t (~33%) of sediment; the distal part around the Ca Mau Peninsula has received ~55 × 10 9 t (~42%) of sediment; and the remaining ~35 × 10 9 t (~25%) has accumulated within the central transition area, although the coastline and shoreface in this area are presently eroding. The spatially averaged 1000-yr-scale accumulate rate is up to 2 cm/yr. Compared to other tide-dominated fluvial dispersal systems, the Mekong River system has a relatively young (≤1000 yr) subaqueous delta, a shallow rollover at 4–6 m water depth, gentle foreset gradients (0.03–0.57°), and a short cross-shelf dimension of 15–20 km within 20-m water depth. Like the Amazon, Po, and Yangtze rivers, the Mekong River has developed a pervasive along-shelf deposit, which in this case extends > 250 > 300km to the southwest as a result of the superimposed tidal processes, wave-induced resuspension, and a strong low-flow season coastal current.

Published

2017

9. Determining rates of sediment accumulation on the Mekong shelf: Timescales, steady-state assumptions, and radiochemical tracers

Author

J.P. Liu, David J. DeMaster, Charles A. Nittrouer, T. T. Nguyen, and Emily Eidam

Subjects

Total organic carbon, Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, δ13C, Continental shelf, Sediment, Geology, Aquatic Science, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Seafloor spreading, Current (stream), River mouth, Seabed, 0105 earth and related environmental sciences

Abstract

Thirty-two kasten cores, collected from the proximal Mekong continental shelf, have been analyzed for their excess 210Pb distributions in an effort to establish rates of sediment accumulation over the past 100 years. The length of the cores varied from 0.5 to 3 m, and stations sampled topset, foreset, and bottomset beds (water depths 7–21 m). Apparent excess 210Pb sediment accumulation rates ranged from > 10 cm/y (no down-core decrease of excess activity over 300 cm core length) near the Song Hau river mouth, to 1–3 cm/y in topset and foreset beds within 20–50 km of the river mouth, to rates as low as 0.4 cm/y in cores from bottomset beds. The 210Pb sediment accumulation rates yield an overall sediment burial rate of 6.1 × 1013 g/y for the proximal deltaic deposits, which corresponds to 43% of the total modern Mekong sediment burial on the southern Vietnam shelf (1.4 × 1014 g/y; based on our 210Pb and seismic data and 210Pb data from the literature). This shelf burial rate is in reasonable agreement with current long-term estimates of Mekong River sediment discharge (1.3–1.6 × 1014 g/y) from the literature. The inventory of excess 210Pb in the proximal Mekong deltaic deposits indicates that the shoreward flow of offshore water (entrained during river/ocean mixing) is approximately twice the flow of the Mekong freshwater discharge. Organic-carbon 14C ages were measured on 10 cores from the proximal Mekong delta and compared to 210Pb sediment accumulation rates in the same core. The 210Pb accumulation rates in all 10 cores were considered to be more robust and accurate than the 14C geochronologies, primarily because of down-core variations in the source of organic carbon deposited on the seafloor (old terrestrial carbon versus younger marine carbon). Variations in the source of organic carbon accumulating in the seabed were resolved by measuring the δ13C value of the seabed organic carbon.

Published

2017

10. Modelling suspended sediment dynamics on the subaqueous delta of the Mekong River

Author

Chris Wackerman, Dano Roelvink, Johan Reyns, Vo Quoc Thanh, and Emily Eidam

Subjects

Hydrology, Delta, geography, River delta, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Front (oceanography), Sediment, Geology, 02 engineering and technology, Aquatic Science, Oceanography, 01 natural sciences, Deposition (geology), 020801 environmental engineering, Erosion, Environmental science, Sediment transport, Sedimentary budget, 0105 earth and related environmental sciences

Abstract

Fluvial sediment is the major source for the formation and development of the Mekong Delta. This paper aims to analyse the dynamics of suspended sediment and to investigate the roles of different processes in order to explore flux pattern changes. We applied modelling on two scales, comprising a large-scale model (the whole delta) to consider the upstream characteristics, particularly the Tonle Sap Lake's flood regulation, and a smaller-scale model (tidal rivers and shelf) to understand the sediment processes on the subaqueous delta. A comprehensive comparison to in-situ measurements and remote sensing data demonstrated that the model is capable of qualitatively simulating sediment dynamics on the subaqueous delta. It estimates that the Mekong River supplied an amount of 41.5 mil tons from April 2014 to April 2015. A substantial amount of sediment delivered by the Mekong River is deposited in front of the river mouths in the high flow season and resuspended in the low flow season. A sensitivity analysis shows that waves, baroclinic effects and bed composition strongly influence suspended sediment distribution and transport on the shelf. Waves in particular play an essential role in sediment resuspension. The development of this model is an important step towards an operational model for scientific and engineering applications, since the model is capable of predicting tidal propagation and discharge distribution through the main branches, and in predicting the seasonal SSC and erosion/deposition patterns on the shelf, while it is forced by readily available inputs: discharge at Kratie (Cambodia), GFS winds, ERA40 reanalysis waves, and TPXO 8v1 HR tidal forcing.

Published

2017

11. Direct observations of submarine melt and subsurface geometry at a tidewater glacier

Author

David A. Sutherland, Jason M. Amundson, C. Kienholz, Jonathan D. Nash, Emily Eidam, R. H. Jackson, D. Duncan, Roman J. Motyka, and W. P. Dryer

Subjects

geography, Multidisciplinary, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ocean current, Tidewater glacier cycle, Ice calving, Submarine, Glacier, Geometry, 010502 geochemistry & geophysics, 01 natural sciences, Current (stream), 13. Climate action, 14. Life underwater, Ice sheet, Geology, 0105 earth and related environmental sciences, Tidewater

Abstract

Underwater melting How fast does warm ocean water melt glaciers that terminate in the sea? That question is central to understanding how fast ice sheets may lose mass, and thus how fast sea level will rise, in response to global warming, but there are few data about the process. Sutherland et al. used repeat multibeam sonar surveys to observe an Alaskan subsurface tidewater glacier face to create a time series of its melting and calving patterns. They observed melt rates up to a hundred times larger than those predicted by theory, observations that compel us to reevaluate predictions of such ice loss. Science , this issue p. 369

Published

2019

12. Tidally dominated sediment dispersal offshore of a small mountainous river: Elwha River, Washington State

Author

Emily Eidam, Andrea S. Ogston, Charles A. Nittrouer, and Jonathan A. Warrick

Subjects

Delta, Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Dam removal, Sediment, Geology, Aquatic Science, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, River mouth, Biological dispersal, Submarine pipeline, Sedimentary budget, Seabed, 0105 earth and related environmental sciences

Abstract

Sediment supplied by small mountainous rivers (SMRs) represents a major fraction of the global ocean sediment budget. Studies from the past two decades have shown that much of this sediment is dispersed by episodic wind and wave energy along storm-dominated coasts. In tidally dominated environments, however, different transport styles and deposits may result from persistent tidal dispersal. This study investigates episodic sediment releases generated by dam removal from a SMR in Washington State, in order to evaluate the mechanics of tidally dominated sediment dispersal in an energetic marine environment. The results indicate that asymmetric tidal currents with peak magnitudes of ∼50 to >80 cm/s produce daily sediment export in the direction of the dominant tidal phase (i.e., the semi-diurnal phase with faster currents and longer duration), resulting in dispersal of fluvially derived fine sediment to distal sinks. These effects are observed throughout all seasons in the presence or absence of wave events. During the first two years of dam removal, more than 8 million tonnes of sediment were discharged to the coast. The net result was little to no change in grain size at 10–60 m water depth across >70% of the seabed offshore of the river mouth. Over the remaining ∼2 to 3 km2 of the subaqueous delta, several cm of mud and sand accumulated in a sheltered coastal embayment adjacent to the river mouth. These results demonstrate that SMR discharge events may form patchy, isolated deposits—or even no deposits—along coastlines with strong tidal currents, in contrast to the mid-shelf mud belts formed on storm-dominated shelves. Over longer timescales, knowledge of the erosional capacity of local and regional tidal currents may be key to interpreting the terrestrial event record preserved in (or possibly excluded from) marine SMR deposits.

Published

2016

13. Hydrography and energetics of a cold subpolar fjord: Andvord Bay, western Antarctic Peninsula

Author

Martin Truffer, Emily Eidam, Mark A. Merrifield, Hank Statscewich, Craig R. Smith, Øyvind Lundesgaard, Peter Winsor, and Brian Powell

Subjects

0106 biological sciences, Katabatic wind, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Geology, Glacier, Fjord, Aquatic Science, Physical oceanography, 01 natural sciences, Oceanography, Circumpolar deep water, Glacial period, Meltwater, Bay, 0105 earth and related environmental sciences

Abstract

Fjords along the western Antarctic Peninsula contain rich marine ecosystems and tidewater glaciers potentially sensitive to ocean change, but much is unknown about the physical oceanography of these fjords. This paper presents a comprehensive description of the physical environment of Andvord Bay, a glacial fjord located in the Gerlache Strait on the northern end of the Peninsula. Measurements were collected as part of the FjordEco program between November 2015 and March 2017, including during three research cruises and from a number of fixed installations (sub-surface moorings, time lapse cameras, and automatic weather stations). Andvord Bay is located just north of a sill in the Gerlache Strait. This sill inhibits the direct influence of warm Upper Circumpolar Deep Water from the shelf, and deep waters in the fjord are therefore relatively cold. As a result, glaciers in Andvord Bay are not subject to the substantial ocean-driven retreat observed farther south on the Peninsula. Instead, mass flux from the glaciers occurs mainly through calving. The influence of meltwater in Andvord Bay is small compared to glacial fjords in the Arctic and in the South Shetland Islands, although summer freshening is evident in the fjord near-surface layer, likely as a result of glacial inputs. The combination of surface freshening and the absence of strong mean wind forcing in the fjord results in salinity stratification extending well into the euphotic zone, providing advantageous conditions for phytoplankton blooms. Andvord Bay is generally dynamically quiet compared to the ambient ocean, with the exception of during local katabatic wind events. Exchange with the Gerlache Strait is weak, although the deep waters of the fjord are replenished on an annual scale through slow lateral exchange with the outside. In addition, deep convection may play a role in ventilating subsurface waters in winter.

Published

2020

14. Large-scale dam removal on the Elwha River, Washington, USA: Coastal geomorphic change

Author

Guy Gelfenbaum, Andrea S. Ogston, Andrew W. Stevens, Emily Eidam, Ian M. Miller, and Jonathan A. Warrick

Subjects

Hydrology, geography, geography.geographical_feature_category, River delta, Dam removal, Erosion, River mouth, Sediment, Sediment transport, Sedimentary budget, Geology, Deposition (geology), Earth-Surface Processes

Abstract

Two dams on the Elwha River, Washington State, USA trapped over 20 million m3 of mud, sand, and gravel since 1927, reducing downstream sediment fluxes and contributing to erosion of the river's coastal delta. The removal of the Elwha and Glines Canyon dams, initiated in September 2011, induced massive increases in river sediment supply and provided an unprecedented opportunity to examine the geomorphic response of a coastal delta to these increases. Detailed measurements of beach topography and nearshore bathymetry show that ~ 2.5 million m3 of sediment was deposited during the first two years of dam removal, which is ~ 100 times greater than deposition rates measured prior to dam removal. The majority of the deposit was located in the intertidal and shallow subtidal region immediately offshore of the river mouth and was composed of sand and gravel. Additional areas of deposition include a secondary sandy deposit to the east of the river mouth and a muddy deposit west of the mouth. A comparison with fluvial sediment fluxes suggests that ~ 70% of the sand and gravel and ~ 6% of the mud supplied by the river was found in the survey area (within about 2 km of the mouth). A hydrodynamic and sediment transport model, validated with in-situ measurements, shows that tidal currents interacting with the larger relict submarine delta help disperse fine sediment large distances east and west of the river mouth. The model also suggests that waves and currents erode the primary deposit located near the river mouth and transport sandy sediment eastward to form the secondary deposit. Though most of the substrate of the larger relict submarine delta was unchanged during the first two years of dam removal, portions of the seafloor close to the river mouth became finer, modifying habitats for biological communities. These results show that river restoration, like natural changes in river sediment supply, can result in rapid and substantial coastal geomorphological responses.

Published

2015