COASTAL ENGINEERING an International Journal for Coastal, Harbour and Offshore Engineers

Total Page:16

File Type:pdf, Size:1020Kb

COASTAL ENGINEERING an International Journal for Coastal, Harbour and Offshore Engineers COASTAL ENGINEERING An International Journal for Coastal, Harbour and Offshore Engineers AUTHOR INFORMATION PACK TABLE OF CONTENTS XXX . • Description p.1 • Audience p.1 • Impact Factor p.1 • Abstracting and Indexing p.1 • Editorial Board p.2 • Guide for Authors p.3 ISSN: 0378-3839 DESCRIPTION . Coastal Engineering is an international medium for coastal engineers and scientists. Combining practical applications with modern technological and scientific approaches, such as mathematical and numerical modelling, laboratory and field observations and experiments, it publishes fundamental studies as well as case studies on the following aspects of coastal, harbour and offshore engineering: waves, currents and sediment transport; coastal, estuarine and offshore morphology; technical and functional design of coastal and harbour structures; morphological and environmental impact of coastal, harbour and offshore structures. AUDIENCE . Civil Engineers. IMPACT FACTOR . 2020: 4.830 © Clarivate Analytics Journal Citation Reports 2021 ABSTRACTING AND INDEXING . Applied Mechanics Reviews Current Contents Geotechnical Abstracts Marine Science Contents Tables Oceanographic Literature Review Pascal Francis Engineering Village - GEOBASE Engineering Index Scopus Science Citation Index INSPEC AUTHOR INFORMATION PACK 24 Sep 2021 www.elsevier.com/locate/coastaleng 1 EDITORIAL BOARD . Editor-in-Chief Iñigo J. Losada, University of Cantabria, Environmental Hydraulics Institute, Santander, 39005, Cantabria, Spain Honorary Editors-in-Chief E.W. Bijker H.F. Burcharth, Aalborg, Denmark Associate Editors P. Nielsen, University of Queensland, Brisbane, Queensland, Australia M.R.A. van Gent, TU Delft & Deltares, Delft, Netherlands, Delft, Netherlands Advisory Editorial Board T.E. Baldock, University of Queensland, Brisbane, Queensland, Australia G. Bellotti, Roma Tre University, Roma, Italy M. Brocchini, Polytechnic University of Marche, Ancona, Italy D. Callaghan, University of Queensland, Brisbane, Queensland, Australia E.D. Christensen, Technical University of Denmark, Kgs Lyngby, Denmark D. Cox, Oregon State University, Corvallis, Oregon, United States of America M. Dibajnia, W F Baird and Associates Coastal Engineers Ltd Oakville, Oakville, Ontario, Canada L. Franco, Roma Tre University, Roma, Italy D.R. Fuhrman, Technical University of Denmark, Kgs Lyngby, Denmark H. Gotoh, Kyoto University, Kyoto, Japan S.C. Hsiao, National Cheng Kung University, Tainan, Taiwan J.L. Irish, Virginia Tech University Bookstore, Blacksburg, Virginia, United States of America D.-S. Jeng, Griffith University School of Engineering and Built Environment, Southport, Queensland, Australia T.V. Karambas, University of the Aegean Department of Marine Sciences, Mytilini, Greece J.T. Kirby, University of Delaware, Newark, Delaware, United States of America A. Lamberti, IRCCS University Hospital of Bologna S Orsola-Malpighi Polyclinic, Bologna, Italy J.L. Lara, University of Cantabria, Santander, Spain M. Larson, Lund University, Lund, Sweden P.Z. Lin, Sichuan University State Key Laboratory of Hydraulics and Mountain River Engineering, Chengdu, China P.L.F. Liu, Cornell University, Ithaca, New York, United States of America M.A. Losada, University of Granada Superior Technical School of Roads Channels and Ports Engineering, Granada, Spain P.A. Madsen, Technical University of Denmark, Kgs Lyngby, Denmark J.M. McKee Smith, US Army Engineer Research and Development Center, Vicksburg, Mississippi, United States of America J.R. Medina, Polytechnic University of Valencia, Valencia, Spain N. Mori, Kyoto University, Kyoto, Japan D. Myrhaug, Norwegian University of Science and Technology Department of Marine Technology, Trondheim, Norway T. O’Donoghue, University of Aberdeen, Aberdeen, United Kingdom D.E. Reeve, Swansea University, Swansea, United Kingdom A. Reniers, Delft University of Technology, Delft, Netherlands D. Roelvink, IHE Delft Institute for Water Education, Delft, Netherlands A. Sánchez-Arcilla, Polytechnic University of Catalonia, Barcelona, Spain S. Sato, The University of Tokyo, Tokyo, Japan H.A. Schäffer, SchafferWaves, København, Denmark M.J.F. Stive, Delft University of Technology, Delft, Netherlands P. Troch, Ghent University, Gent, Belgium X. Yu, Tsinghua University, Beijing, China AUTHOR INFORMATION PACK 24 Sep 2021 www.elsevier.com/locate/coastaleng 2 GUIDE FOR AUTHORS . Submission checklist You can use this list to carry out a final check of your submission before you send it to the journal for review. Please check the relevant section in this Guide for Authors for more details. Ensure that the following items are present: One author has been designated as the corresponding author with contact details: • E-mail address • Full postal address All necessary files have been uploaded: Manuscript: • Include keywords • All figures (include relevant captions) • All tables (including titles, description, footnotes) • Ensure all figure and table citations in the text match the files provided • Indicate clearly if color should be used for any figures in print Graphical Abstracts / Highlights files (where applicable) Supplemental files (where applicable) Further considerations • Manuscript has been 'spell checked' and 'grammar checked' • All references mentioned in the Reference List are cited in the text, and vice versa • Permission has been obtained for use of copyrighted material from other sources (including the Internet) • A competing interests statement is provided, even if the authors have no competing interests to declare • Journal policies detailed in this guide have been reviewed • Referee suggestions and contact details provided, based on journal requirements For further information, visit our Support Center. BEFORE YOU BEGIN Ethics in publishing Please see our information on Ethics in publishing. Declaration of competing interest All authors must disclose any financial and personal relationships with other people or organizations that could inappropriately influence (bias) their work. Examples of potential conflicts of interest include employment, consultancies, stock ownership, honoraria, paid expert testimony, patent applications/ registrations, and grants or other funding. Authors should create a declaration of competing interest statement using this tool and upload to the submission system at the Attach Files step. Note: Please do not convert the .docx template to another file type. Author signatures are not required. Submission declaration and verification Submission of an article implies that the work described has not been published previously (except in the form of an abstract, a published lecture or academic thesis, see 'Multiple, redundant or concurrent publication' for more information), that it is not under consideration for publication elsewhere, that its publication is approved by all authors and tacitly or explicitly by the responsible authorities where the work was carried out, and that, if accepted, it will not be published elsewhere in the same form, in English or in any other language, including electronically without the written consent of the copyright- holder. To verify originality, your article may be checked by the originality detection service Crossref Similarity Check. Preprints Please note that preprints can be shared anywhere at any time, in line with Elsevier's sharing policy. Sharing your preprints e.g. on a preprint server will not count as prior publication (see 'Multiple, redundant or concurrent publication' for more information). AUTHOR INFORMATION PACK 24 Sep 2021 www.elsevier.com/locate/coastaleng 3 Use of inclusive language Inclusive language acknowledges diversity, conveys respect to all people, is sensitive to differences, and promotes equal opportunities. Content should make no assumptions about the beliefs or commitments of any reader; contain nothing which might imply that one individual is superior to another on the grounds of age, gender, race, ethnicity, culture, sexual orientation, disability or health condition; and use inclusive language throughout. Authors should ensure that writing is free from bias, stereotypes, slang, reference to dominant culture and/or cultural assumptions. We advise to seek gender neutrality by using plural nouns ("clinicians, patients/clients") as default/wherever possible to avoid using "he, she," or "he/she." We recommend avoiding the use of descriptors that refer to personal attributes such as age, gender, race, ethnicity, culture, sexual orientation, disability or health condition unless they are relevant and valid. These guidelines are meant as a point of reference to help identify appropriate language but are by no means exhaustive or definitive. Author contributions For transparency, we encourage authors to submit an author statement file outlining their individual contributions to the paper using the relevant CRediT roles: Conceptualization; Data curation; Formal analysis; Funding acquisition; Investigation; Methodology; Project administration; Resources; Software; Supervision; Validation; Visualization; Roles/Writing - original draft; Writing - review & editing. Authorship statements should be formatted with the names of authors first and CRediT role(s) following. More details and an example Changes to authorship Authors are expected to consider carefully the list and order of authors before submitting their manuscript and provide the definitive list of authors at the time of the original submission. Any addition, deletion or rearrangement of author names in the authorship list
Recommended publications
  • ENVIRONMENT in COASTAL ENGINEERING: DEFINITIONS and EXAMPLES** Cyril Galvin, M. ASCE* ABSTRACT in Current Usage, Environmental A
    ENVIRONMENT IN COASTAL ENGINEERING: DEFINITIONS AND EXAMPLES** Cyril Galvin, M. ASCE* ABSTRACT In current usage, environmental aspects of coastal engineering design include aspects of ecology and aesthe- tics, as well as environment. In practice, the aspect of environment is a limited one, considering man's surround- ings, with the works of man left out. The increased consid- eration of environmental aspects over the past 15 years has brought real benefits to the coastal engineering profession, as well as obvious problems. One problem is a mythology of coastal processes that has become widely accepted. Priori- ties in coastal engineering design remain a structure that will last a useful lifetime and perform its intended func- tion without creating new problems. After satisfying these fundamental requirements, the structure should minimize ecological change, and fit pleasingly in its setting. INTRODUCTION Design and THE Environment. A coastal structure must remain standing when hit by the most severe waves, currents, and winds that can reasonably be expected during its intended lifetime. Waves, currents, and winds are basic elements of the physical environment. In this structural sense, good coastal engineering is always sensitive to the environment. But the designer who creates a structure that doesn't fall down has not necessarily solved a coastal problem. The structure must also perform a function, without creating significant new problems. it must reduce beach erosion, prevent flooding, maintain a channel, provide a quiet anchorage, convey liquids across the shore, or serve other functions. There are groins standing out at sea after the beach has eroded away; jetties exist that enclose a deposit of sand rather than a navigable waterway; some seawalls are regularly overtopped by moderate seas; water intakes are silted in.
    [Show full text]
  • Coastal Risk Assessment for Ebeye
    Coastal Risk Assesment for Ebeye Technical report | Coastal Risk Assessment for Ebeye Technical report Alessio Giardino Kees Nederhoff Matthijs Gawehn Ellen Quataert Alex Capel 1230829-001 © Deltares, 2017, B De tores Title Coastal Risk Assessment for Ebeye Client Project Reference Pages The World Bank 1230829-001 1230829-00 1-ZKS-OOO1 142 Keywords Coastal hazards, coastal risks, extreme waves, storm surges, coastal erosion, typhoons, tsunami's, engineering solutions, small islands, low-elevation islands, coral reefs Summary The Republic of the Marshall Islands consists of an atoll archipelago located in the central Pacific, stretching approximately 1,130 km north to south and 1,300 km east to west. The archipelago consists of 29 atolls and 5 reef platforms arranged in a double chain of islands. The atolls and reef platforms are host to approximately 1,225 reef islands, which are characterised as low-lying with a mean elevation of 2 m above mean sea leveL Many of the islands are inhabited, though over 74% of the 53,000 population (2011 census) is concentrated on the atolls of Majuro and Kwajalein The limited land size of these islands and the low-lying topographic elevation makes these islands prone to natural hazards and climate change. As generally observed, small islands have low adaptive capacity, and the adaptation costs are high relative to the gross domestic product (GDP). The focus of this study is on the two islands of Ebeye and Majuro, respectively located on the Ralik Island Chain and the Ratak Island Chain, which host the two largest population centres of the archipelago.
    [Show full text]
  • Functional Design of Coastal Structures
    FUNCTIONALFUNCTIONAL DESIGNDESIGN OFOF David R. Basco, Ph.D, P.E. Director, The Coastal Engineering Center Old Dominion University,Norfolk, Virginia USA 23529 [email protected] DESIGNDESIGN OFOF COASTALCOASTAL STRUCTURESSTRUCTURES •• FunctionFunction ofof structurestructure •• StructuralStructural integrityintegrity •• PhysicalPhysical environmentenvironment •• ConstructionConstruction methodsmethods •• OperationOperation andand maintenancemaintenance OUTLINEOUTLINE •• PlanPlan formform layoutlayout - headland breakwaters - nearshore breakwaters - groin fields • WaveWave runuprunup andand overtopping*overtopping* - breakwaters and revetments (seawalls, beaches not covered here) •• WaveWave reflectionsreflections (materials(materials includedincluded inin notes)notes) * materials from ASCE, Coastal Engineering Short Course, CEM Preview, April 2001 SHORESHORE PARALLELPARALLEL BREAKWATERS:BREAKWATERS: HEADLANDHEADLAND TYPETYPE Design Rules, Hardaway et al. 1991 • Use sand fill to create tombolo for constriction from land • Set berm elevation so tombolo always present at high tide • Set Yg/Lg =• 1.65 for stable shaped beach • Set Ls/Lg = 1 • Always combine with new beach fill • See CEM 2001 V-3 for details KEYKEY VARIABLESVARIABLES FORFOR NEARSHORENEARSHORE BREAKWATERBREAKWATER DESIGNDESIGN Dally and Pope, 1986 Definitions: Y = breakwater distance from nourished shoreline Ls = length of breakwater Lg = gap distance d = water depth at breakwater (MWL) ds = water depth• at breakwater (MWL) •Tombolo formation: Ls/Y = 1.5 to 2 single = 1.5 system •Salient formation: Ls/ = 0.5 to 0.67 = 0.125 long systems (a) (b) Process Parameter Description 1. Bypassing Dg/Hb Depth at groin tip/breaking wave height 2. Permeability • Over-passing Zg (y) Groin elevation across profile, tidal range • Through-passing P(y) Grain permeability across shore • Shore-passing Zb/R Berm elevation/runup elevation 3. Longshore transport Qn/Qg Net rate/gross rate Property Comment 1. Wave angle and wave height Accepted.
    [Show full text]
  • Environmentally Friendly Coastal Protection the ECOPRO Project Abstract
    Environmentally Friendly Coastal Protection The ECOPRO Project Brendan Dollard1 Abstract In the battle to preserve land against the ravages of the sea man has created many inappropriate protection structures on the coast. Often the coastline which is being protected is, inherently, in dis-equilibrium with nature. When combined with the increased recreational usage of the coastal zone, the rise in sea level and the increased incidence of storms, accelerated erosion rates are often the result. The Environmentally Friendly Coastal Protection project, or ECOPRO for short, developed a coastal erosion assessment method for the non-specialist. It devised a system for optimising erosion monitoring and developed a guide to select of an appropriate coastal protection response. The project results are contained in the ECOPRO Code of Practice. This 320-page guide explains the steps involved in assessing and monitoring coastal erosion problems, planning protective actions and evaluating their environmental impact. Prepared by the Offshore & Coastal Engineering Unit of Enterprise Ireland, it is the result of four years of work which was supported under the EU LIFE Programme and drew on expertise from Ireland, Northern Ireland and Denmark. This paper presents details of the project and the development of the Code. 1. Introduction In recent years it has become accepted that the coastline is a valuable natural resource which needs careful and sensitive management. This is especially so in the case of small island countries where the coastal zone has a direct and major influence on the economic welfare of the country. Coastal erosion has always been seen as one of the main threats to this resource and for centuries man has been fighting what was perceived as the ravages of the sea.
    [Show full text]
  • Engineering for Climate: Coastal Engineering Methods for Resilient Atoll Nations in Productive Oceans
    Engineering for Climate Coastal Engineering Methods for Resilient Atoll Nations in Productive Oceans Presented to Asian Development Bank (ADB), Maldives By: Michael J.H. Foley, Ph.D., P.E. August 28, 2019 Welcome to Our Future Climate 10/8/19 2 Beach & Shoreline Erosion Mitigation Protecting Against Sea Level Rise Nature-Based Designs to Restore Eroded Shorelines & Enhance Coastal Resilience • Engineering • Design • Ecosystems • Technology 3 Land Subsidence Drivers of Coastal Erosion Rainfall Betio Runoff Currents Wave Runup Bairiki Rising Sea Levels 4 Sea Level Rise Increases Shoreline Wave Heights and Flooding Beach Reef Crest Reef Flat Forereef Sea Level Rise Bad for Atoll Islands Reef Crest Reef Flat Lagoon Forereef Mitigation of Erosion Hazards Adaptation Managed Retreat 10/8/19 7 Mitigation of Shoreline Erosion Armored Slopes Vertical Walls 10/8/19 8 Beaches Natural Erosion Protection 10/8/19 9 Mitigation of Beach & Shoreline Erosion Sand Nourishment Vegetated Coastal Berm Before After 10/8/19 10 Beach Stabilization Groins Breakwaters 10/8/19 11 Design by Nature – Beach Stabilization 10/8/19 12 Crescent Beaches Natural Biomimicry Crescent Engineered Beach Lagoon Crescent Beach Natural Lagoon Source: Google Earth Waves Move Sand Long-Shore Sediment Transport Cross-Shore Sediment Transport Source: Google Earth Source: Google Earth Wave Reef Interactions - Refraction Swell Deep Submerged Reef Water Channel Rotated Wave Crest Submerged Reef Waves Slow, Rotate and Converge Swell Wave Energy Diverted Source: Google Earth Source: Google
    [Show full text]
  • Coastal Management Software to Support the Decision-Makers to Mitigate Coastal Erosion
    Journal of Marine Science and Engineering Article Coastal Management Software to Support the Decision-Makers to Mitigate Coastal Erosion Carlos Coelho * , Pedro Narra, Bárbara Marinho and Márcia Lima RISCO & Civil Engineering Department, Aveiro University, Campus Universitário de Santiago, 3810-193 Aveiro, Portugal; [email protected] (P.N.); [email protected] (B.M.); [email protected] (M.L.) * Correspondence: [email protected] Received: 4 December 2019; Accepted: 8 January 2020; Published: 11 January 2020 Abstract: There are no sequential and integrated approaches that include the steps needed to perform an adequate management and planning of the coastal zones to mitigate coastal erosion problems and climate change effects. Important numerical model packs are available for users, but often looking deeply to the physical processes, demanding big computational efforts and focusing on specific problems. Thus, it is important to provide adequate tools to the decision-makers, which can be easily interpreted by populations, promoting discussions of optimal intervention scenarios in medium to long-term horizons. COMASO (coastal management software) intends to fill this gap, presenting a group of tools that can be applied in standalone mode, or in a sequential order. The first tool should map the coastal erosion vulnerability and risk, also including the climate change effects, defining a hierarchy of priorities where coastal defense interventions should be performed, or limiting/constraining some land uses or activities. In the locations identified as priorities, a more detailed analysis should consider the application of shoreline and cross-shore evolution models (second tool), allowing discussing intervention scenarios, in medium to long-term horizons. After the defined scenarios, the design of the intervention should be discussed, both in case of being a hard coastal structure or an artificial nourishment (third type of tools).
    [Show full text]
  • Application of Timber Groynes in Coastal Engineering
    Application of timber groynes in coastal engineering M.Sc. Thesis U.H. Perdok December 2002 Application of timber groynes in coastal engineering Draft M.Sc. Thesis U.H. Perdok December 2002 Section of Hydraulic Engineering Faculty of Civil Engineering and Geosciences Delft University of Technology Thesis committee: Mr. M.P. Crossman, HR Wallingford Ltd Dr. ir. A.L.A. Fraaij, Delft University of Technology Mr. J.D. Simm, HR Wallingford Ltd Prof. dr. ir. M.J.F. Stive, Delft University of Technology Ir. H.J. Verhagen, Delft University of Technology Cover picture: Severely abraded timber groyne at Bexhill, East Sussex, UK (April 2002) ii Preface This thesis presents the results of my graduation project and will lead to the completion of the Masters of Science degree in Civil Engineering at the Faculty of Civil Engineering and Geosciences, Delft University of Technology (The Netherlands). With this thesis I hope to provide with guidance on the use of timber groynes in coastal engineering and to promote the appropriate use of available timber. I was privileged to execute the major part of this research project at Hydraulics Research Wallingford (United Kingdom) during a six-month placement period. While working on the “Manual on the use of timber in coastal and fluvial engineering”, I had the opportunity to learn from the experience of contractors, consultants, local authorities and timber specialists. As this report is largely based on their experience, I would like to thank the following people for their cooperation: Simon Howard and John Andrews (Posford-Haskoning), Andrew Bradbury (New Forest District Council), Brian Holland (Arun District Council), David Harlow (Bournemouth Borough Council), Stephen McFarland (Canterbury City Council) and John Williams (TRADA).
    [Show full text]
  • Concept Designs for a Groyne Field on the Far North Nsw Coast
    CONCEPT DESIGNS FOR A GROYNE FIELD ON THE FAR NORTH NSW COAST I Coghlan 1, J Carley 1, R Cox 1, E Davey 1, M Blacka 1, J Lofthouse 2 1 Water Research Laboratory (WRL), School of Civil and Environmental Engineering, The University of New South Wales, Manly Vale, NSW 2Tweed Shire Council (TSC), Murwillumbah, NSW Introduction On the open coast of NSW, many options exist to adapt to the hazards of erosion and recession. Perhaps the most common historical approach to counter the erosion and recession hazard is to construct a seawall or revetment to protect the existing foreshore. Other alternatives include the construction of a submerged breakwater, assisted beach recovery and/or beach nourishment. For beaches with a littoral drift imbalance, the construction of one or more groyne structures is a further possibility. This paper presents two different concept designs for a long term groyne field at Kingscliff Beach. Background Information Case Study: Kingscliff Beach Kingscliff Beach, located at the southern end of Wommin Bay on the far north coast of NSW (Figure 1), is a section of the Tweed coastline with built assets at immediate risk from coastal hazards. Ongoing erosion in the last few years has resulted in substantial loss of beach amenity and community land. Storm erosion episodes between 2009 and 2012 severely impacted the Kingscliff Beach Holiday Park (KBHP). This section is also affected by moderate ongoing underlying shoreline recession (WBM, 2001). To manage the Kingscliff Beach foreshore (Figure 2) in the longer term, Tweed Shire
    [Show full text]
  • Wave Runup on Atoll Reefs
    MSc. Thesis Wave runup on atoll reefs Ellen Quataert January 2015 Front cover: Aerial view of the southern tip of the Kwajalein Atoll in the Republic of the Marshall Islands. Source: www.fayeandsteve.com Wave runup on atoll reefs Ellen Quataert 1210070-000 © Deltares, 2015, B Keywords Runup, atoll reef, XBeach, infragravity wave, wave-induced setup, incident swash, infragravity swash, Kwajalein Summary The aim of this research was to take the first step in understanding the wave runup process on an atoll reef using the XBeach model. Field data collected from 3 November 2013 to 13 April 2014 at Kwajalein Atoll in the Republic of the Marshall Islands was used. The dataset included data on bathymetry, waves, water levels and wave-induced runup. The data was analysed and subsequently used to model the hydrodynamics across the reef and the wave runup. The hydrostatic and non-hydrostatic XBeach models were used to capture both components of runup, infragravity and incident swash. Finally, a conceptual model was created to investigate the effect of variations in the atoll reef parameter space on the wave runup. References 1210070-000 Version Date Author Initials Review Initials Approval Initials Jan. 2015 E. Quataert A.R. van Dongeren F. Hoozemans A.A. van Rooijen State final Wave runup on atoll reefs Wave runup on atoll reefs by Ellen Quataert in partial fulfilment of the requirements for the degree of Master of Science in Civil Engineering Delft University of Technology January 2015 In collaboration with: Graduation committee: Prof. dr. ir. M.J.F. Stive Delft University of Technology ir.
    [Show full text]
  • Highways in the Coastal Environment: Assessing Extreme Events
    Archival Superseded by HEC-25 3rd edition - January 2020 Publication No. FHWA-NHI-14-006 October 2014 U.S. Department of Hydraulic Engineering Circular No. 25 – Volume 2 Transportation Federal Highway Administration Archival Superseded by HEC-25 3rd edition - January 2020 Highways in the Coastal Environment: Assessing Extreme Events Archival Superseded by HEC-25 3rd edition - January 2020 TECHNICAL REPORT DOCUMENTATION PAGE Archival Superseded by HEC-25 3rd edition - January 2020 Form DOT F 1700.7 (8-72) Reproduction of completed page authorized Archival Superseded by HEC-25 3rd edition - January 2020 Table of Contents Table of Contents ........................................................................................................... i List of Figures ................................................................................................................ v List of Tables ................................................................................................................ vii Acknowledgements ........................................................................................................ ix Glossary ........................................................................................................................ xi List of Acronyms .......................................................................................................... xxi Chapter 1 – Introduction ................................................................................................ 1 1.1 Background ........................................................................................................
    [Show full text]
  • FIELD MEASUREMENTS of SWASH INDUCED PRESSURES WITHIN a SANDY BEACH D. P. Horn1, T. E. Baldock2, A. J. Baird3 and T. E. Mason2 Ab
    FIELD MEASUREMENTS OF SWASH INDUCED PRESSURES WITHIN A SANDY BEACH D. P. Horn1, T. E. Baldock2, A. J. Baird3 and T. E. Mason2 Abstract This paper describes field measurements of near-surface hydraulic gradients within a sandy beach during individual swash cycles. We show several different types of behaviour which may have implications for swash zone sediment transport: (1) measurements of swash depth; (2) 'unloading' events with large upward-acting hydraulic gradients; (3) infiltration events with smaller downward-acting hydraulic gradients; (4) situations where the probes lower in the bed measure significantly lower heads than the probe at the surface, leading to strongly downward-acting hydraulic gradients; and (5) measurements in the capillary fringe. Large hydraulic gradients, which are more than sufficient to induce fluidisation, occur in the top 15 mm of the bed under swash and backwash. These large hydraulic gradients, which occur only in the very top section of the bed, may coincide with a significant depth of water (up to 40 mm), which suggests the potential for entrainment of the fluidised bed under backwash. Introduction Accretion and deposition on the foreshore is a function of the interaction of surface and subsurface flow regimes in the swash zone, and an understanding of the interaction between surface and groundwater flows is necessary to model swash zone sediment transport. Previous research has suggested that infiltration and exfiltration in the swash zone may be important mechanisms in beach profile changes, governing sediment deposition and erosion rates above mean sea level. Much of this work has focused on examining the link between tidally-induced groundwater flows and swash infiltration/exfiltration, with the assumption that changes in swash volume would alter swash/backwash flow asymmetry.
    [Show full text]
  • An Evaluation of Design Factors and Performance of Groynes
    Transactions on the Built Environment vol 70, © 2003 WIT Press, www.witpress.com, ISSN 1743-3509 An evaluation of design factors and performance of groynes P. Dong Division of Civil Engineering, Faculty of Science and Engineering, University of Dundee. Abstract Groynes are among the oldest structures in wide use today for controlling coastal erosion. Due to the complexities of the physical processes involved, predictions of groyne performance are not always reliable despite the prolific use of sophisticated numerical models. Site specific knowledge obtained from post- construction monitoring remains an indispensable source of knowledge for engineers in designing groynes. This paper reports the analysis of a recently conducted questionnaire survey on the most important factors which influence the design of groynes and perception of the performance of existing groynes. It was found that the greatest importance was placed on the effectiveness of groynes in holding sediment locally while the least importance was placed on the negative effects that building groynes can have on both the natural and human environments. It was also found that a large proportion of the existing groynes seemed to have achieved their design objectives with the rock groynes performing particularly well. 1 Introduction Whether built as stand-alone structures or as a part of coastal protection scheme involving beach nourishment or seawalls, the groynes are designed to control longshore sediment transport and retain sediments on beaches. Due to the complexities of the physical processes involved, the design of groynes is still far from an exact science despite the prolific use of sophisticated numerical models in recent years (Walker et al.
    [Show full text]