GLORIA — GEOMAR Library Ocean Research Information Access

1

Online Resource

High Resolution Morphodynamics and Sedimentary Evolution of Estuaries. (2005)

FitzGerald, Duncan M.

Dordrecht :Springer Netherlands,

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Keywords: Estuarine sediments. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (364 pages)

Edition: 1st ed.

ISBN: 9781402032967

Series Statement: Coastal Systems and Continental Margins Series ; v.8

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=371982

DDC: 551.3530916

Language: English

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2

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Glaciated Coasts. (1987)

Fitzgerald, Duncan M.

Saint Louis :Elsevier Science & Technology,

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Keywords: Glacial landforms. ; Coasts. ; Electronic books.

Description / Table of Contents: Glaciated Coasts is a collection of articles that deals with shoreline morphologies of glaciated coasts and the processes that formed these coastlines in North America. This book examines nonsandy shorelines and covers a range of geologic and geographic coastal settings in a northern-southern order. This text investigates and compares the glaciated northern shorelines. These shorelines north of the glacial limit are mostly of the primary form in different stages of modification by marine agents. Shorelines are associated with embayments; baymouth barriers in turn enclose embayments. This book describes beaches as having coarse or mixed sediment populations. Most beaches worldwide have gravel clasts that have been rounded and sorted by marine processes. In the southeastern coast of Alaska, active tectonics on a mountainous shoreline is evident. The region also shows emergent and submerging shorelines with a glacial imprint undergoing formation by modern processes. This book also gives examples of gravel beach environments in various coastal settings. This book can prove useful for students of meteorology, oceanography as well as to marine ecologists and biologists. It can also benefit readers whose interest lie with coastal environment or with the general earth sciences.

Type of Medium: Online Resource

Pages: 1 online resource (381 pages)

Edition: 1st ed.

ISBN: 9781483270203

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=1839553

DDC: 551.313

Language: English

Note: Front Cover -- Glaciated Coasts -- Copyright Page -- Table of Contents -- LIST OF CONTRIBUTORS -- PREFACE -- Chapter 1. Geomorphology of a Tectonically Active, Glaciated Coast, South-Central Alaska -- I. Introduction -- II. Physical Setting -- III. Coastal Geomorphology -- IV. Coastal Sedimentary Environments -- V. Summary -- References -- Chapter 2. Fjord Sedimentation in Northern British Columbia -- I. Introduction -- II. Controls on Fjord Development and Sedimentation -- III. Burke Channel-North Bentinck Arm -- References -- Chapter 3. Coarse-Grained Beach Sedimentation under Paraglacial Conditions, Canadian Atlantic Coast -- I. Introduction -- II. Glaciation in Atlantic Canada -- III. Postglacial Relative Sea Level and Tidal Adjustments -- IV. Modern Oceanographic Environment -- V. Beach Morphology and Sediments-Selected Examples -- VI. Beach Development under Varying Sediment-Source Regimes -- VII. Beach Development under Varying Relative-Sea-Level Regimes -- VIII. Beach Development under Varying Dynamic Regimes -- IX. Conclusions -- References -- Chapter 4. An Evolutionary Model for Transgressive Sedimentation on the Eastern Shore of Nova Scotia -- I. Introduction and Objectives -- II. Physical Processes -- III. Relative Sea Level -- IV. Coastal Geology -- V. Eastern Shore Processes and Morphology -- VI. Evolutionary Coastal Model -- VII. Discussion -- VIII. Conclusions -- References -- Chapter 5. Holocene Evolution of the South-Central Coast of Iceland -- I. Introduction -- II. Glaciation -- III. Fluvioglacial Processes -- IV. Coastal Processes -- V. Shoreface and Continental Shelf -- VI. Conclusions -- References -- Chapter 6. An Inventory of Coastal Environments and Classification of Maine's Glaciated Shoreline -- I. Introduction -- II. Coastal Climate -- III. Late Quaternary History -- IV. Bedrock Geology -- V. Methods -- VI. Results. , VII. Discussion -- VIII. Summary -- References -- Chapter 7. Quaternary Stratigraphy of Representative Maine Estuaries: Initial Examination by High- Resolution Seismic Reflection Profiling -- I. Introduction -- II. Geologic Setting -- III. Methods -- IV. Discussion -- V. Conclusions -- References -- Chapter 8. Controls and Zonation of Geomorphology along a Glaciated Coast, Gouldsboro Bay, Maine -- I. Introduction -- II. Physical Setting -- III. Methods -- IV. Geomorphic Classes -- V. Controls of Coastal Geomorphology -- VI. Geomorphic Zonation -- VII. Conclusions -- References -- Chapter 9. Sediment Accumulation Forms, Thompson Island, Boston Harbor, Massachusetts -- I. Introduction and Setting -- II. South Cuspate Spit: Drift Convergence and the Initiation of a Tombolo -- III. North Cuspate Spit: Migrating Spits and Gravel Ridge Forms -- IV. South Longshore Spit: Gravel Overwash and Bar Emergence -- V. Conclusions -- References -- Chapter 10. Source of Pebbles at Mann Hill Beach, Scituate, Massachusetts -- I. Introduction -- II. Mann Hill Beach -- III. Offshore Sediment -- IV. Waves -- V. Wave-Induced Sediment Transport -- VI. Source of the Shingle on Mann Hill Beach -- References -- Chapter 11. Shoreline Development of the Glacial Cape Cod Coastline -- I. Introduction -- II. Glacial Geology of Cape Cod -- III. Coastal Geomorphology of Cape Cod -- IV. Cape Cod's Fulcrum-Nodal Coastline -- V. Fulcrum Cliffline Erosion -- VI. Cape Cod Beach Sediment Patterns -- VII. Barrier Beach Analogs of Cape Cod -- VIII. Conclusion -- References -- Chapter 12. Reworking of Glacial Outwash Sediments along Outer Cape Cod: Development of Provincetown Spit -- I. Introduction -- II. Evolution of Provincetown Spit -- III. Methodology -- IV. Results -- V. Summary and Conclusions -- References -- Index.

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Book

Glaciated coasts (1987)

FitzGerald, Duncan M. ; Northeast Section meeting of the Geological Society of America 1983.

San Diego, Cal. u.a. : Academic Pr.

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Keywords: Glacial landforms ; Coasts ; Aufsatzsammlung ; Glaziales Sediment ; Küste ; Küste ; Glazialmorphologie

Type of Medium: Book

Pages: XV, 364 S , Ill., graph. Darst., Kt

ISBN: 0122578708

URL: https://external.dandelon.com/download/attachments/dandelon/ids/DE0064002DC5CBF723E46C1257A360045DF37.pdf

DDC: 551.3/13

RVK:

RB 10310

RVK:

RB 10295

Language: English

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Refining the model of barrier island formation along a paraglacial coast in the Gulf of Maine (2013)

Hein, Christopher J. ; FitzGerald, Duncan M. ; Carruthers, Emily A. ; [et al.]

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Publication Date: 2022-05-25

Description: Author Posting. © The Author(s), 2012. This is the author's version of the work. It is posted here by permission of Elsevier B.V. for personal use, not for redistribution. The definitive version was published in Marine Geology 307-310 (2012):40-57, doi:10.1016/j.margeo.2012.03.001.

Description: Details of the internal architecture and local geochronology of Plum Island, the longest barrier in the Gulf of Maine, has refined our understanding of barrier island formation in paraglacial settings. Ground-penetrating radar and shallow-seismic profiles coupled with sediment cores and radiocarbon dates provide an 8000-year evolutionary history of this barrier system in response to changes in sediment sources and supply rates as well as variability in the rate of sea-level change. The barrier sequence overlies tills of Wisconsinan and Illinoian glaciations as well as late Pleistocene glaciomarine clay deposited during the post-glacial sea-level highstand at approximately 17 ka. Holocene sediment began accumulating at the site of Plum Island at 7–8 ka, in the form of coarse fluvial channel-lag deposits related to the 50-m wide erosional channel of the Parker River that carved into underlying glaciomarine deposits during a lower stand of sea level. Plum Island had first developed in its modern location by ca. 3.6 ka through onshore migration and vertical accretion of reworked regressive and lowstand deposits. The prevalence of southerly, seaward-dipping layers indicates that greater than 60% of the barrier lithosome developed in its modern location through southerly spit progradation, consistent with a dominantly longshore transport system driven by northeast storms. Thinner sequences of northerly, landward-dipping clinoforms represent the northern recurve of the prograding spit. A 5–6-m thick inlet-fill sequence was identified overlying the lower stand fluvial deposit; its stratigraphy captures events of channel migration, ebb-delta breaching, onshore bar migration, channel shoaling and inlet infilling associated with the migration and eventual closing of the inlet. This inlet had a maximum cross-sectional area of 2800 m2 and was active around 3.5–3.6 ka. Discovery of this inlet suggests that the tidal prism was once larger than at present. Bay infilling, driven by the import of sediment into the backbarrier environment through tidal inlets, as well as minor sediment contribution from local rivers, led to a vast reduction in the bay tidal prism. This study demonstrates that, prior to about 3 ka, Plum Island and its associated marshes, tidal flats, and inlets were in a paraglacial environment; that is, their main source of sediment was derived from the erosion and reworking of glaciogenic deposits. Since that time, Plum Island has been in a state of dynamic equilibrium with its non-glacial sediment sources and therefore can be largely considered to be in a stable, “post-paraglacial” state. This study is furthermore the first in the Gulf of Maine to show that spit accretion and inlet processes were the dominant mechanisms in barrier island formation and thus serves as a foundation for future investigations of barrier development in response to backbarrier infilling.

Description: This study was funded by the Minerals Management Service (now the “Bureau of Ocean Energy Manegement, Regulation and Enforcement”), the USGS Eastern Geology and Paleoclimate Science Center, the USGS National Cooperative Geologic Mapping Program (State Map), a Geological Society of America (GSA) Student Research Grant, the American Association of Petroleum Geologists (AAPG) Grants-in-Aid program, and the Boston University Undergraduate Research Opportunities Program (UROP). Additionally, E. Carruthers was funded in part by the Clare Booth Luce Summer Research Fellowship and C. Hein was funded by the National Science Foundation (NSF) Graduate Research Fellowship.

Keywords: Inlet processes ; Inlet-fill sequence ; Spit accretion ; Barrier-island formation ; Paraglacial ; Ground-penetrating radar

Repository Name: Woods Hole Open Access Server

Type: Preprint

Format: application/pdf

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Coastal impacts due to sea-level rise (2008)

FitzGerald, Duncan M. ; Fenster, Michael S. ; Argow, Britt A. ; [et al.]

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Publication Date: 2022-05-25

Description: Author Posting. © Annual Reviews, 2007. This is the author's version of the work. It is posted here by permission of Annual Reviews for personal use, not for redistribution. The definitive version was published in Annual Review of Earth and Planetary Sciences 36 (2008): 601-647, doi:10.1146/annurev.earth.35.031306.140139.

Description: Recent estimates by Intergovermental Panel on Climate Change (2007) are that global sea level will rise from 0.18 to 0.59 m by the end of this century. Rising sea level not only inundates low-lying coastal regions, but it also contributes to the redistribution of sediment along sandy coasts. Over the long-term, sea-level rise (SLR) causes barrier islands to migrate landward while conserving mass through offshore and onshore sediment transport. Under these conditions, coastal systems adjust to SLR dynamically while maintaining a characteristic geometry that is unique to a particular coast. Coastal marshes are susceptible to accelerated SLR because their vertical accretion rates are limited and they may drown. As marshes convert to open water, tidal exchange through inlets increases, which leads to sand sequestration on tidal deltas and erosion of adjacent barrier shorelines.

Keywords: Barrier islands ; Tidal inlets ; Salt marsh ; Wetlands ; Inundation ; Estuaries ; Equilibrium slope

Repository Name: Woods Hole Open Access Server

Type: Preprint

Format: application/pdf

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Shoreline dynamics along a developed river mouth barrier island: Multi-decadal cycles of erosion and event-driven mitigation (2019)

Hein, Christopher J. ; Fallon, Andrew R. ; Rosen, Peter ; [et al.]

Frontiers Media

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Publication Date: 2022-10-26

Description: © The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Hein, C. J., Fallon, A. R., Rosen, P., Hoagland, P., Georgiou, I. Y., FitzGerald, D. M., Morris, M., Baker, S., Marino, G. B., & Fitzsimons, G. Shoreline dynamics along a developed river mouth barrier island: Multi-decadal cycles of erosion and event-driven mitigation. Frontiers in Earth Science, 7(103), (2019), doi:10.3389/feart.2019.00103.

Description: Human modifications in response to erosion have altered the natural transport of sediment to and across the coastal zone, thereby potentially exacerbating the impacts of future erosive events. Using a combination of historical shoreline-change mapping, sediment sampling, three-dimensional beach surveys, and hydrodynamic modeling of nearshore and inlet processes, this study explored the feedbacks between periodic coastal erosion patterns and associated mitigation responses, focusing on the open-ocean and inner-inlet beaches of Plum Island and the Merrimack River Inlet, Massachusetts, United States. Installation of river-mouth jetties in the early 20th century stabilized the inlet, allowing residential development in northern Plum Island, but triggering successive, multi-decadal cycles of alternating beach erosion and accretion along the inner-inlet and oceanfront beaches. At a finer spatial scale, the formation and southerly migration of an erosion “hotspot” (a setback of the high-water line by ∼100 m) occurs regularly (every 25–40 years) in response to the refraction of northeast storm waves around the ebb-tidal delta. Growth of the delta progressively shifts the focus of storm wave energy further down-shore, replenishing updrift segments with sand through the detachment, landward migration, and shoreline-welding of swash bars. Monitoring recent hotspot migration (2008–2014) demonstrates erosion (〉30,000 m3 of sand) along a 350-m section of beach in 6 months, followed by recovery, as the hotspot migrated further south. In response to these erosion cycles, local residents and governmental agencies attempted to protect shorefront properties with a variety of soft and hard structures. The latter have provided protection to some homes, but enhanced erosion elsewhere. Although the local community is in broad agreement about the need to plan for long-term coastal changes associated with sea-level rise and increased storminess, real-time responses have involved reactions mainly to short-term (〈5 years) erosion threats. A collective consensus for sustainable management of this area is lacking and the development of a longer-term adaptive perspective needed for proper planning has been elusive. With a deepening understanding of multi-decadal coastal dynamics, including a characterization of the relative contributions of both nature and humans, we can be more optimistic that adaptations beyond mere reactions to shoreline change are achievable.

Description: This work was supported financially by the National Science Foundation (NSF) Coastal SEES program (awards OCE 1325430 and OCE 1325366). PH also received partial support through the NSF Coupled Natural-Human Systems program (award AGS 1518503) and the Northeast Regional Sea Grant and Woods Hole Sea Grant Programs (NOAA Cooperative Agreement award NA14OAR4170074).

Keywords: Tidal-inlet dynamics ; Beach erosion ; Coastal adaptation ; Developed beach ; Shoreline change

Repository Name: Woods Hole Open Access Server

Type: Article

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7

Electronic Resource

Morphologic and stratigraphic evolution of muddy ebb-tidal deltas along a subsiding coast: Barataria Bay, Mississippi River delta (2004)

Fitzgerald, Duncan M. ; Kulp, Mark ; Penland, Shea ; [et al.]

Oxford, UK : Blackwell Science Ltd

Sedimentology 51 (2004), S. 0

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ISSN: 1365-3091

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: The Barataria barrier coast formed between two major distributaries of the Mississippi River delta: the Plaquemines deltaic headland to the east and the Lafourche deltaic headland to the west. Rapid relative sea-level rise (1·03 cm year−1) and other erosional processes within Barataria Bay have led to substantial increases in the area of open water (〉 775 km2 since 1956) and the attendant bay tidal prism. Historically, the increase in tidal discharge at inlets has produced larger channel cross-sections and prograding ebb-tidal deltas. For example, the ebb delta at Barataria Pass has built seaward 〉 2·2 km since the 1880s. Shoreline erosion and an increasing bay tidal prism also facilitated the formation of new inlets. Four major lithofacies characterize the Barataria coast ebb-tidal deltas and associated sedimentary environments. These include a proximal delta facies composed of massive to laminated, fine grey-brown to pale yellow sand and a distal delta facies consisting of thinly laminated, grey to pale yellow sand and silty sand with mud layers. The higher energy proximal delta deposits contain a greater percentage of sand (75–100%) compared with the distal delta sediments (60–80%). Associated sedimentary units include a nearshore facies consisting of horizontally laminated, fine to very fine grey sand with mud layers and an offshore facies that is composed of grey to dark grey, laminated sandy silt to silty clay. All facies coarsen upwards except the offshore facies, which fines upwards. An evolutionary model is presented for the stratigraphic development of the ebb-tidal deltas in a regime of increasing tidal energy resulting from coastal land loss and tidal prism growth. Ebb-tidal delta facies prograde over nearshore sediments, which interfinger with offshore facies. The seaward decrease in tidal current velocity of the ebb discharge produces a gradational contact between proximal and distal tidal delta facies. As the tidal discharge increases and the inlet grows in dimensions, the proximal and distal tidal delta facies prograde seawards. Owing to the relatively low gradient of the inner continental shelf, the ebb-tidal delta lithosome is presently no more than 5 m thick and is generally only 2–3 m in thickness. The ebb delta sediment is sourced from deepening of the inlet and the associated channels and from the longshore sediment transport system. The final stage in the model envisages erosion and segmentation of the barrier chain, leading to a decrease in tidal discharge through the former major inlets. This process ultimately results in fine-grained sedimentation seaward of the inlets and the encasement of the ebb-tidal delta lithosome in mud. The ebb-tidal deltas along the Barataria coast are distinguished from most other ebb deltas along sand-rich coasts by their muddy content and lack of large-scale stratification produced by channel cut-and-fills and bar migration.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-3091.2004.00663.x

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Classification of paraglacial barrier systems: coastal New England, USA (1999)

Fitzgerald, Duncan M. ; Van Heteren, Sytze

Oxford UK : Blackwell Science Ltd

Sedimentology 46 (1999), S. 0

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ISSN: 1365-3091

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: The New England coast harbours a wide variety of barrier forms, which we organize into six barrier-coastline types. The barriers develop in response to the relative importance of several spatially and temporally variable parameters, particularly antecedent topography and geology, sediment abundance and size, exposure to wave and tidal energy and sea-level history. The six coastline types can also be identified in other paraglacial regions. Existing barrier-coastline classification schemes do not allow consistent subdivision of paraglacial barrier coasts. This paper presents a new scheme that is applicable to paraglacial and non-paraglacial barrier coasts alike. Aside from hydrodynamic regime, which forms the basis of the barrier classification most commonly used to date, it includes a compartmentalization factor. Sediment-starved ‘isolated’ (‘type 1’) barrier coastlines are characterized by short, widely spaced barriers. Small, localized updrift and offshore sources have provided sediment for short barriers along ‘clustered headland-separated’ (‘type 2’) barrier coastlines. Various amounts of sediment from larger updrift and offshore glaciofluvial deposits or directly from rivers have formed the longer barriers along ‘wave-dominated mainland-segmented’ (‘type 3a’), ‘mixed-energy mainland-segmented’ (‘type 3b’), ‘wave-dominated inlet-segmented’ (‘type 4a’) and ‘mixed-energy inlet-segmented’ (‘type 4b’) barrier coastlines. Geomorphic form, grain size and stratigraphy can be used to characterize individual barriers along barrier coastlines. Most paraglacial barriers form as spits, but many are transformed subsequently. Welded barriers are common along ‘type 1’ and ‘type 2’ coasts. Baymouth barriers are characteristic of ‘type 3’ coasts, and barrier islands occur exclusively along ‘type 4’ coasts. The coarsest grained barriers are located along ‘type 1’ and ‘type 2’ coasts. Progradational barrier sections are concentrated along ‘type 3’ and ‘type 4’ coasts with abundant sediment supply, but are also present along ‘type 2’ coasts. Temporary increases in sediment supply, common in paraglacial regions, result in transitions between retrogradational and progradational barrier behaviour, which may be recognized on shore-perpendicular stratigraphic cross-sections.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1046/j.1365-3091.1999.00266.x

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Electronic Resource

Radar facies of paraglacial barrier systems: coastal New England, USA (1998)

Heteren, Sytze Van ; Fitzgerald, Duncan M. ; Mckinlay, Paul A. ; [et al.]

Oxford UK : Blackwell Science Ltd, UK

Sedimentology 45 (1998), S. 0

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ISSN: 1365-3091

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: Analysis of a large data base of ground-penetrating-radar (GPR) profiles from both natural and developed paraglacial barriers along the coast of New England has allowed identification of eight reflection configurations that characterize this type of mid- to high-latitude coastal environment. Bedrock anchor points yield primarily hyperbolic configurations, whereas glacial anchor points and sediment-source areas are characterized by chaotic, parallel, and tangential-oblique configurations. Beaches and dunes produce predominantly sigmoidal oblique, hummocky, reflection-free, and bounding-surface configurations. Back-barrier sediments may yield basin-fill configurations, but generally include abundant signal-attenuating units.The GPR data, calibrated with information from cores, were collected across swash-aligned and drift-aligned barriers in a variety of wave- and tidal-energy settings. Application of a 120-MHz antenna, as used in this study, enables portrayal of a range of sedimentary units, from individual bedforms (on single records) to entire barrier elements (using large numbers of intersecting GPR sections), at maximum vertical resolutions that vary between 0·2 m and 0·7 m.The most important drawback of GPR in the coastal environment is attenuation of the electromagnetic (EM) signal by layers of salt-marsh peat or by brackish or salty groundwater, primarily along barrier edges. This disadvantage is offset by many benefits. Data can be collected at rates of several km per day, making GPR an excellent reconnaissance tool. A core that is used in the calibration of GPR data can be matched with great accuracy to its position on the complementary GPR record, allowing detailed correlation between lithostratigraphy and reflection configuration.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1046/j.1365-3091.1998.00150.x

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10

Electronic Resource

A flood-dominated mesotidal inlet (1984)

FitzGerald, Duncan M. ; Fink, L. Kenneth ; Lincoln, Jonathan M.

Springer

Geo-marine letters 3 (1984), S. 17-22

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ISSN: 1432-1157

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Tidal inlets along the mesotidal coast of Maine contrast with those from other parts of the world by being dominated by flood-tidal currents. Analysis of the factors responsible for flood or ebb dominance indicates factors external to the backbarrier environment. We suggest that the flood dominance is caused by both a steepening of the tidal wave in the Gulf of Maine and the shallow depth of the ebb-tidal delta and spit platform. Flood currents are typically 10–20 cm/sec stronger than the ebb at the inlet throat. The flood dominance results in a significant net landward transport of sediment into the backbarrier.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02463437

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