DOCSLIB.ORG

Not. Little Reference Is Made to the Pioneering Work Carried out by The

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Not. Little Reference Is Made to the Pioneering Work Carried out by The 85 not. Little reference is made to the pioneering work published material from scholars the world over. carried out bythe US Army Corps ofEngineers and Applied Geomorphology is, then, an international the authors neglect the rudimentary fact that groin text in its content, scope and application. emplacement must be attuned to site specific Verstappen sees the main application of geo­ nearshore dynamics. The remaining seven papers, morphology in the fields of geology, pedology, hy­ comprising Sessions VII (Structural Form and drology, vegetation and topographic mapping as Materials) and VITI (Cliff Stabilization) are of con­ these relate to the analysis and development of siderable interest and certainly serve to round off natural resources, the amelioration of environmen­ the entire proceedings nicely. Indeed I think that in tal hazards, of rural development and urbanization many past symposia the importance of these aspects and in civil engineering. Accordingly his book is of coastal protection have never truly been subdivided into three sections. In Section A he exploited. explores the roles of geomorphology in the acquisi­ In summary, this is a good compilation, par­ tion of knowledge about natural environments and ticularly valuable to those concerned with the many resources by the different groups of earth scien­ aspects of coastal protection in the UK. My only tists. Geomorphology and appropriate use of the major concern is the obvious lack of attention paid natural environmentis tackled in SectionB with the to the many US shore protection schemes. The UK foci being upon rural land use, urbanization, mineral has the prodigious advantage of learning from mis­ resources and engineering. Section C, perhaps the takes made by the US. I recommend Shoreline Pro­ heart of the book, is an illustration and analysis of tection internationally to those working on similar geomorphological methodologies for use in planned problems on the proviso that they satisfy only their developments. Here, the concept and practice of curiosity. By no means do I recommend it as a geomorphological surveys is expounded and then reference for abatingcoastal problems. Myguess is, applied to the study of flood and drought suscep­ you simply will not find too many answers. tibilities, to slope stability and erosion surveys, to violent hazards such as avalanches, volcanic erup­ Gregory Stone tions and earthquakes, and in terrain classification University of Maryland Throughout sections A and B, Verstappen is pre­ College Park, Maryland senting primarily the conceptual and empirical bases for an Applied Geomorphology through a wide range of case studies whilst some appropriate methodol­ Applied Geomorphology: Geomorphological ogies and techniques are outlined in Section C. The Surveys for Environmental Development, by contribution to geomorphology, environmental sur­ H Th Verstappen, 1983, Elsevier, 437p. US$83.25, vey and resource development planning for which ISBN 0-444-42181-5. both Verstappen and ITC are justifiably renowned lies especiallyinthe mappingofenvironmental pro­ Applied Geomorphology is a large book, beautifully perties and processes from a diversity of remotely printed on glossy paper. Written byone ofthe world's sensed imagery and in the field. These emphases leading geomorphologists from a lifetime's field are clearlyapparent inthe book and their utility can and professional experience in Asia, Africa, Europe be appreciated from the lavish use ofair photographs and South America it is a major work on environ­ singly, in stereopairs and stereotriplets, many an­ mental science. Professor Verstappen is a doyen of notated, of thematic and synthetic maps and of the International Institute for Aerial Survey and ground photographs. These examples and illus­ Earth Science at Enschede, The Netherlands, to trations are drawn from a wide diversity of geo­ which come students from every continent for pro­ graphical environments mostly - but not solely fessional and academic training in cartography, -in the developingworlds ofAsia, Mrica, southern aerial survey, geomorphology, resource planning Europe and SOLlth America and help to foster in the and development, and from whence go its teachers reader an awareness ofthe massive problems faced to carry out contractual and private research like­ by some societies and their earth scientists. wise in many countries and environments. This Some of the applications of geomorphology pre­ book is builtnotonly on Verstappen's own acquired sented by Professor Verstappen lie outside the wisdom and knowledge but also on that of his col­ mainstream of his research and the work of the leagues, studentsand, as the listofreferences atthe I T.C. and, as a consequence, are handled with less end of each chapter shows, on a very large body of facility than the others. For example the discussion Journal of Coastal Research, Vol. 2, No.1, 1986 86 on the exploration for mineral deposits reveals a flow through beaches are based heavily on impor­ limited familiarity with American, French and British ted ideas, and offer little that is new. An interesting work Applied geomorphology in coastal environ­ paper on coastal sediment budget changes follow­ ments is even more thinly treated with but a few ing dam construction should have been in the pages being devoted to coastal engineering, coastal management section, if anywhere. A paper on Holo­ flooding and dune encroachment. cene coastal changes in The Netherlands appears The main strengths of the book lie in its wide to have been presented at the wrong meeting. Perhaps ranging demonstration ofthe use of geomorphology the most useful contribution is that by Winter on in general and of the fundamental importance of the relationship between surfzone circulations and mapping in particular. In this it is superb. Verstappen's diatom populations, although the mathematics are Applied Geomorphology, like his Remote Sensing in offputting, and perhaps unnecessary. The section is Geomorphology, should be in the course bibliogra­ concluded by a 'where-do-we-go-from-here' type phies of every proselytizer of geomorphology and summary, that was not worth including. teacher of environmental science and should, of The chemistry section follows the same basic course, be well thumbed by every planner, developer pattenl, although the review is a little more conven­ and manager of natural environmental resources, tional and most of the papers are biased towards although individuals will not feel inclined to spend ecological processes. Pugh's paperon nutrient cycl­ eighty-three dollars from their own pockets to buy ing is particularly clear and concise, ifnot very pro­ this book found, while the two papers by Quinlan and her associates are both enjoyable and of a high standard Martin Thorp The standout section of the book is undoubtably University College the ecology. McLachlan's review is excellent and Dublin, Ireland will be much read by aspiring students of beach ecology. He has made a great effort to mesh physi­ cal, chemical, and biological concepts and apply Sandy Beaches as Ecosystems, edited by A. them to sandy beaches. The subsequent 200 pages McLachlan and T. Erasmus, 1983, Dr. W. Junk, ofecology range across primary and secondary pro­ The Hague, 757p. US$ 120.00, ISBN 90-6193-77-1. ducers, decomposers and bacteria. Many papers highlight the intimate connections between near­ This volume arose from the First International shore communities and their generally hostile en­ Symposium on Sandy Beaches held in PortElizabeth vironmente.g. Lewis and Schaeferon surfplankton, South Africa in 1983. It has been published as num­ and Woolridge on Mysis. It is also clear that much ber 19 in the series Developments in Hydrobiology. good work is being carried out in South Africa on The volume is divided into five main sections cover­ beach ecology; I particularly liked the papers on ing the physical (13 contributions), chemical (10), shore birds and on kelp. ecology (20), ecophysiology and autecology (11) The ecophysiology section is really a continua­ and management(5), plus 18 abstracts. Each ofthe tion of the preceeding ecological one. The final sec­ main sections starts wi th a review (or partial review) tion on management is a disappointment. The pa­ and ends with a workshop report. pers are not indicative of the state-of-the-art, Clark's The papers are, as with all symposia volumes, a review is missing (a summary is provided, Sf emingly mixed bag. The host country contributions have a scribbled from no~es by one ofthe audience). Bird's tendency to he parochial, the international con­ review of global beach changes has, or is, appearing tributions somewhat general. Much of the subject all over the place and the remainder are just dis­ matter of the latter has been published before. parate examples. The physical section is typical. It starts with an Overall this is an important book. J suspect ecol­ idiosyncratic review of nearshore processes by ogists will like it for the physical and chemical sec­ Swart, marred by poor diagrams and a tendency to tions, non-ecologists, like myself, for the ecology. It cite obscure internal reports instead of the correct does however manage to convey a sense ofmultidis­ sources. 'rhe review is followed by good papers by ciplinary togtherness, which often eludes this type Chapman, Bird and Shortand Wrighton Australian of volume. I ended up learning a lot from readingit beaches and Aubrey on the American ones, although There are a few typographical errors, but probably all are re-hashes of their earlier work. The 'local' less then one might expect from a camera-ready papers on crenellate coasts. beach structures and text. Some of the figures are illegible, some photo- Journal of Coastal Research. Vol. 2. No.1. 19Rfl.
Load more

Recommended publications
  • Santa Cruz County Coastal Climate Change Vulnerability Report
    Santa Cruz County Coastal Climate Change Vulnerability Report JUNE 2017 CENTRAL COAST WETLANDS GROUP MOSS LANDING MARINE LABS | 8272 MOSS LANDING RD, MOSS LANDING, CA Santa Cruz County Coastal Climate Change Vulnerability Report This page intentionally left blank Santa Cruz County Coastal Climate Change Vulnerability Report i Prepared by Central Coast Wetlands Group at Moss Landing Marine Labs Technical assistance provided by: ESA Revell Coastal The Nature Conservancy Center for Ocean Solutions Prepared for The County of Santa Cruz Funding Provided by: The California Ocean Protection Council Grant number C0300700 Santa Cruz County Coastal Climate Change Vulnerability Report ii Primary Authors: Central Coast Wetlands group Ross Clark Sarah Stoner-Duncan Jason Adelaars Sierra Tobin Kamille Hammerstrom Acknowledgements: California State Ocean Protection Council Abe Doherty Paige Berube Nick Sadrpour Santa Cruz County David Carlson City of Capitola Rich Grunow Coastal Conservation and Research Jim Oakden Science Team David Revell, Revell Coastal Bob Battalio, ESA James Gregory, ESA James Jackson, ESA GIS Layer support AMBAG Santa Cruz County Adapt Monterey Bay Kelly Leo, TNC Sarah Newkirk, TNC Eric Hartge, Center for Ocean Solution Santa Cruz County Coastal Climate Change Vulnerability Report iii Contents Contents Summary of Findings ........................................................................................................................ viii 1. Introduction ................................................................................................................................
    [Show full text]
  • Coastal and Ocean Engineering
    May 18, 2020 Coastal and Ocean Engineering John Fenton Institute of Hydraulic Engineering and Water Resources Management Vienna University of Technology, Karlsplatz 13/222, 1040 Vienna, Austria URL: http://johndfenton.com/ URL: mailto:[email protected] Abstract This course introduces maritime engineering, encompassing coastal and ocean engineering. It con- centrates on providing an understanding of the many processes at work when the tides, storms and waves interact with the natural and human environments. The course will be a mixture of descrip- tion and theory – it is hoped that by understanding the theory that the practicewillbemadeallthe easier. There is nothing quite so practical as a good theory. Table of Contents References ....................... 2 1. Introduction ..................... 6 1.1 Physical properties of seawater ............. 6 2. Introduction to Oceanography ............... 7 2.1 Ocean currents .................. 7 2.2 El Niño, La Niña, and the Southern Oscillation ........10 2.3 Indian Ocean Dipole ................12 2.4 Continental shelf flow ................13 3. Tides .......................15 3.1 Introduction ...................15 3.2 Tide generating forces and equilibrium theory ........15 3.3 Dynamic model of tides ...............17 3.4 Harmonic analysis and prediction of tides ..........19 4. Surface gravity waves ..................21 4.1 The equations of fluid mechanics ............21 4.2 Boundary conditions ................28 4.3 The general problem of wave motion ...........29 4.4 Linear wave theory .................30 4.5 Shoaling, refraction and breaking ............44 4.6 Diffraction ...................50 4.7 Nonlinear wave theories ...............51 1 Coastal and Ocean Engineering John Fenton 5. The calculation of forces on ocean structures ...........54 5.1 Structural element much smaller than wavelength – drag and inertia forces .....................54 5.2 Structural element comparable with wavelength – diffraction forces ..56 6.
    [Show full text]
  • Chesapeake Bay Cliff Erosion in Calvert County- and to Make Recommendations to the Board of County Commissioners on Issues Relating to Cliff Stabilization
    DEPARTMENT OF COMMUNITY PLANNING AND BUILDING INTEROFFICE MEMORANDUM TO: Board of County Commissioners VIA: Terry Shannon, County Admini VIA: Thomas Barnett, Director / FROM: Dave Brownlee, Principal Environmental Pla ner DATE: May 7, 2014 SUBJECT: Final Report of the Cliff Stabilization Advisory Committee Background: The Cliff Stabilization Advisory Committee was established by the Board of County Commissioners in November 2010. Virginia (Ginger) Haskell, PhD was appointed chairperson. The Committee was charged with responding to the State Steering Committee Report, "Chesapeake Bay Cliff Erosion in Calvert County- and to make recommendations to the Board of County Commissioners on issues relating to cliff stabilization. The Committee is made up of residents representing Chesapeake Bay shoreline communities. Discussion: The Committee held monthly public meetings between January 2011 and June 2013. In an effort to educate the Committee and the community, the Committee invited geologists, biologists, engineers, academics and government officials to give presentations at 9 of their meetings. The Committee's final report (attached) has 17 recommendations and includes the response to the State Steering Committee Report (Appendix E). The Committee continued to meet between June 2013 and April 2014 to complete the report. Dr. Haskell will present the report to the Board of County Commissioners on May 13, 2014 (see attached PowerPoint). A list of the Committee members is given on pages 15-16 of the Final Report and on the last slide of the PowerPoint. Conclusion/Recommendation: Recommend that the BOCC review the Final Report and submit the Final Report to Department Heads to get feedback on implementation of the recommendations within the report.
    [Show full text]
  • North Sheppey Erosion Study Volume 1: Coastal
    NORTH SHEPPEY EROSION STUDY VOLUME 1: COASTAL ADAPTATION STUDY Client: Consultant: Swale Borough Council Engineering Services Swale House, Canterbury City Council East Street, Military Road Sittingbourne, Canterbury, ME10 3HT CT1 1YW OCTOBER 2011 Canterbury City Council Engineering Services 0 LIST OF CONTENTS Page VOLUME 1: COASTAL ADAPTATION STUDY Executive Summary 3 1. Background 4 2. Description of site 6 3. Higher level plans 25 4. Historical and Coastal Evolution 31 5. Geology and Morphology 34 6. Aerial photography 36 7. Lidar Airborne laser scanning 37 8. Historic Ordnance Survey Records 39 9. Parameters 40 10. Management of Coastal Erosion Options 50 11. Do Nothing Scenario 62 12. Economic Appraisal 65 13. Environmental Assessment 67 14. Monitoring and Public Warning 69 15. Consultation 71 16. Recommendations and Implementation 72 References 75 List of Photographs Photo 1- The Leas looking west 7 Photo 2- East End of Minster 11 Photo 3- Minster cliffs and sea defences looking west 14 Photo 4- Fly tipping near Royal Oak Point, cliffs highly vegetated. 15 Photo 5- View from Redcot Caravan Park looking across to Lazy Days park 16 Photo 6- Redcot caravan park 16 Photo 7- Looking West from Ashcroft caravan park 17 Photo 8- Barrows Brook 18 Photo 9- Recent mud run at Ashcroft caravan park 19 Photo 10-Warden Point west of Warden Springs 20 Photo 11- Looking east towards Warden Point 20 Photo 12- Rock armour at Warden Bay revetment looking west 23 Photo 13- Rear scarp of recent slide Cliff Drive, Warden Bay 23 Photo 14- Land slide at Warden Point November 1971 43 Photo 15- Cliff warning sign 70 List of Tables 35 Table 1- Geological Details Table 2- Average Future Erosion for England and Wales 41 Table 3- Historic and predicted future erosion rates 42 Table 4- Recorded land slide history 44 Table 5- Relative sea level rise from UKCP09 47 Table 6- Recommended contingency allowances for net sea level rise PPS25 48 Table 7- Property adaptation, financial options 61 Table 8- Summary of impacts resulting from a do nothing scenario.
    [Show full text]
  • Chesapeake Bay Cliff Erosion in Calvert County Draft Steering Committee Report
    Chesapeake Bay Cliff Erosion in Calvert County Draft Steering Committee Report Calvert County Maryland Department of Natural Resources Maryland Department of the Environment United States Army Corps of Engineers United States Fish and Wildlife Service Maryland Emergency Management Agency October 26, 2010 TABLE OF CONTENTS I. INTRODUCTION 4 II. THE STEERING COMMITTEE 5 III. OVERVIEW 5 A. The Cliffs in Calvert County 5 1. Homes on the Cliffs 2. Soil Erosion 3. Calvert County Zoning – Building Restrictions 4. Efforts to Address Soil Erosion B. Considerations 8 1. Geology 2. Engineering 3. The Puritan Tiger Beetle III. SHORT­TERM POTENTIAL SOLUTIONS 10 A. Site Characterization 10 1. Soil Composition 2. Shoreline Structures 3. Degree of Slope 4. Soil Erosion at the Bank 5. Vegetative Cover 6. Puritan Tiger Beetle Habitat 7. Other Data 8. Characterization B. Assessment of Properties at Highest Potential Immediate Risk 13 1. Ryan and Associates 2. International Residential Code 3. Site‐Specific Analysis C. Potential Short­Term Solutions 14 1. MEMA/FEMA Funding 2. The County MEMA/FEMA Application 2 3. Implementation IV. MEDIUM­TERM POTENTIAL SOLUTIONS 17 A. Engineering 17 1. Cliff Stabilization 2. Shoreline Stabilization. B. Impacts on the Puritan Tiger Beetle 18 1. The Regulatory Framework 2. Population Viability Analysis 3. Minimization and Mitigation 4. FWS and DNR Assistance V. LONG­TERM POTENTIAL SOLUTIONS 19 VI. CONCLUSION 20 VII. REFERENCES 20 3 I. INTRODUCTION Following a February 20, 2010 Town Hall meeting in Calvert County, state, federal and county agencies formed a Steering Committee to study and develop recommendations to address the impact of shoreline erosion on houses located near the eroding cliffs in Calvert County.
    [Show full text]
  • Managing Climate Change Hazards in Coastal Areas
    CATALOGUE OF HAZARD MANAGEMENT OPTIONS CI-12 CI-11 CI-10 TSR CI-9 CI-8 PL-1 PL-2 PL-3 CI-7 PL-4 CI-6 PL-5 4 4 3 PL-6 CI-5 2 4 2 4 3 PL-7 CI-4 4 4 PL-8 2 4 4 3 3 PL-9 4 3 2 3 2 3 CI-3 3 3 3 2 PL-10 2 2 3 3 2 3 CI-2 4 2 3 3 4 PL-11 4 3 4 3 2 3 3 2 3 3 3 2 1 PL-12 CI-1 4 4 4 3 3 2 2 1 1 3 3 3 4 4 3 2 3 PL-13 2 3 3 4 2 1 1 3 3 2 R-4 3 4 3 4 4 Tidal inlet/Sand spit/River mouth 1 1 2 2 2 2 2 4 3 3 4 4 4 2 4 2 4 PL-14 R-3 3 4 4 4 2 2 4 3 4 3 4 2 3 3 PL-15 R-2 1 3 4 4 N Y N 4 2 4 4 Y N Y Y N 4 2 3 3 3 PL-16 R-1 1 2 4 N Y N 2 4 Y Y 4 2 2 2 PL-17 1 1 1 4 4 N N 2 FR-22 Y Y 4 4 3 2 3 1 2 1 2 4 N N PL-18 FR-21 1 4 Y Y 4 2 2 3 1 1 N N 2 2 1 2 4 2 2 3 3 PL-19 FR-20 1 Y Sur B/D Sur Y 2 4 3 3 1 1 A B/D B/D N 2 PL-20 2 Sur Sur 4 1 FR-19 1 3 1 A B/D Y 4 2 2 2 A B/D N 4 3 1 PL-21 1 3 4 Sur Sur 2 2 3 FR-18 3 2 A Y 2 3 1 3 4 B/D N 2 PL-22 2 N B B/D 2 3 2 FR-17 2 3 NB Y 4 3 1 3 Y Sur 4 2 PL-23 2 3 N B Any N 3 FR-16 3 3 NB Any Any 4 1 1 Y Any Intermit B/D Y 4 3 2 PL-24 2 2 1 2 1 FR-15 3 Any Any marsh N 2 BA-1 2 1 N Intermit Sur 2 4 2 C 2 4 3 2 3 Y Any mangr Y 2 FR-14 2 4 A 4 BA-2 3 Marsh/ B/D N 2 3 2 4 N C Any Any 1 3 1 Any Any Any tidal at Y 3 FR-13 2 3 Y 1 2 4 BA-3 3 4 M/M Any Sur 3 1 Micro N 4 BA-4 FR-12 2 3 N B Mangr/ 1 1 3 2 4 No Any B/D 2 2 2 2 Y tidal at Y 1 1 BA-5 FR-11 3 1 P Ex Meso/ 3 4 3 N NB Mx Mx N 4 2 2 3 Any Ex macro Sur 2 3 1 C A Y 3 BA-6 FR-10 Y P Any 3 3 2 1 2 B 2 3 3 1 B/D N N P Coral Any 4 3 3 BA-7 FR-9 3 1 R 2 2 2 3 1 NB Any Any isl Sediment Y Y Ex Any Sur 2 2 2 1 2 BA-8 FR-8 2 2 2 3 4 Mx plain Any N N Flat Mx B Y 4 4 4 3 4 BA-9 FR-7 3 2
    [Show full text]
  • Managing Climate Change Hazards in Coastal Areas
    MAIN MANUAL CI-12 CI-11 CI-10 TSR CI-9 CI-8 PL-1 PL-2 PL-3 CI-7 PL-4 CI-6 PL-5 4 4 3 PL-6 CI-5 2 4 2 4 3 PL-7 CI-4 4 4 PL-8 2 4 4 3 3 PL-9 4 3 2 3 2 3 CI-3 3 3 3 2 PL-10 2 2 3 3 2 3 CI-2 4 2 3 3 4 PL-11 4 3 4 3 2 3 3 2 3 3 3 2 1 PL-12 CI-1 4 4 4 3 3 2 2 1 1 3 3 3 4 4 3 2 3 PL-13 2 3 3 4 2 1 1 3 3 2 R-4 3 4 3 4 4 Tidal inlet/Sand spit/River mouth 1 1 2 2 2 2 2 4 3 3 4 4 4 2 4 2 4 PL-14 R-3 3 4 4 4 2 2 4 3 4 3 4 2 3 3 PL-15 R-2 1 3 4 4 N Y N 4 2 4 4 Y N Y Y N 4 2 3 3 3 PL-16 R-1 1 2 4 N Y N 2 4 Y Y 4 2 2 2 PL-17 1 1 1 4 4 N N 2 FR-22 Y Y 4 4 3 2 3 1 2 1 2 4 N N PL-18 FR-21 1 4 Y Y 4 2 2 3 1 1 N N 2 2 1 2 4 2 2 3 3 PL-19 FR-20 1 Y Sur B/D Sur Y 2 4 3 3 1 1 A B/D B/D N 2 PL-20 2 Sur Sur 4 1 FR-19 1 3 1 A B/D Y 4 2 2 2 A B/D N 4 3 1 PL-21 1 3 4 Sur Sur 2 2 3 FR-18 3 2 A Y 2 3 1 3 4 B/D N 2 PL-22 2 N B B/D 2 3 2 FR-17 2 3 NB Y 4 3 1 3 Y Sur 4 2 PL-23 2 3 N B Any N 3 FR-16 3 3 NB Any Any 4 1 1 Y Any Intermit B/D Y 4 3 2 PL-24 2 2 1 2 1 FR-15 3 Any Any marsh N 2 BA-1 2 1 N Intermit Sur 2 4 2 C 2 4 3 2 3 Y Any mangr Y 2 FR-14 2 4 A 4 BA-2 3 Marsh/ B/D N 2 3 2 4 N C Any Any 1 3 1 Any Any Any tidal at Y 3 FR-13 2 3 Y 1 2 4 BA-3 3 4 M/M Any Sur 3 1 Micro N 4 BA-4 FR-12 2 3 N B Mangr/ 1 1 3 2 4 No Any B/D 2 2 2 2 Y tidal at Y 1 1 BA-5 FR-11 3 1 P Ex Meso/ 3 4 3 N NB Mx Mx N 4 2 2 3 Any Ex macro Sur 2 3 1 C A Y 3 BA-6 FR-10 Y P Any 3 3 2 1 2 B 2 3 3 1 B/D N N P Coral Any 4 3 3 BA-7 FR-9 3 1 R 2 2 2 3 1 NB Any Any isl Sediment Y Y Ex Any Sur 2 2 2 1 2 BA-8 FR-8 2 2 2 3 4 Mx plain Any N N Flat Mx B Y 4 4 4 3 4 BA-9 FR-7 3 2 2 3 4 Y hard rock B/D Barrier
    [Show full text]
  • Coastal Erosion on Sydney's Southern Beaches Study Report
    Coastal Erosion on Sydney’s southern beaches Study Report at the Water Research Laboratory of the University of New South Wales, Sydney, Australia in association with the Bergische Universität Wuppertal Univ.-Prof. Dr.-Ing. H. Kaldenhoff by cand.-Ing. Marcus Dätig Sydney, January 2001 Contents 1 Introduction 1 2 Beaches in the coastal zone 2 3 The Beach System 5 4 Coastal erosion and beach processes 6 5 Human Response to Natural Coastal Hazards 9 5.1 The Establishment of Buffer Zones . 9 5.2 Beach Protection Systems . 9 5.2.1 Seawalls . 9 5.2.2 Groynes . 10 5.3 Sand Nourishment . 10 5.4 Dune Stabilization . 10 6 Three Southern Beaches of Sydney 13 6.1 Clovelly Beach . 14 6.2 Coogee Beach . 15 6.3 Maroubra Beach . 16 7 The Coastline Hazards of these beaches 20 7.1 Clovelly Bay . 20 7.1.1 Zone 1: hazard level: minor to moderate . 20 7.1.2 Zone 2: hazard level: minor to serious . 20 7.1.3 Zone 3: hazard level: minor . 21 7.1.4 Zone 4: hazard level: minor to serious . 22 7.1.5 Zone 5: hazard level: low . 22 i CONTENTS ii 7.2 Coogee Bay . 23 7.2.1 Zone 1: hazard level: minor . 23 7.2.2 Zone 2: hazard level: serious . 24 7.2.3 Zone 3: hazard level: minor . 25 7.2.4 Zone 4: hazard level: moderate to serious . 25 7.3 Maroubra Bay . 26 7.3.1 Zone 1: hazard level: moderate . 26 7.3.2 Zone 2: hazard level: serious .
    [Show full text]
  • A Guide to Coastal Erosion Management Practices in Europe
    Service contract B4-3301/2001/329175/MAR/B3 “Coastal erosion – Evaluation of the needs for action” Directorate General Environment European Commission A guide to coastal erosion management practices in Europe January 2004 Prepared by the National Institute of Coastal and Marine Management of the Netherlands TABLE OF CONTENT INTRODUCTION 4 SECTION 1 LESSONS LEARNED FROM THE CASE STUDIES 14 SECTION 2 DETAILED ANALYSIS OF THE CASE STUDIES 28 INTRODUCTION 28 SUMMARY 29 1. REGIONAL SEAS 37 1.1 Introduction 37 1.2 Coastal classification 37 1.3 Erosion 39 1.4 Baltic Sea 40 1.5 North Sea 46 1.6 Atlantic Ocean 54 1.7 Mediterranean Sea 61 1.8 Black Sea 69 2. SOCIO-ECONOMICS AND ENVIRONMENT 75 2.1 Introduction 75 2.2 Baltic Sea 76 2.3 North Sea 80 2.4 Atlantic Ocean 85 2.5 Mediterranean Sea 89 2.6 Black Sea 91 3. POLICY OPTIONS 96 3.1 Introduction 96 3.2 Integrated Coastal Zone Management (ICZM) 98 3.3 Baltic Sea 99 3.4 North Sea 105 3.5 Atlantic Ocean 115 3.6 Mediterranean Sea 124 3.7 Black Sea 129 4. TECHNICAL ANALYSIS 134 4.1 Introduction 134 4.2 Baltic Sea 140 4.3 North Sea 146 4.4 Atlantic Ocean 153 4.5 Mediterranean Sea 160 4.6 Black Sea 167 ANNEX 1 - OVERVIEW OF COMMONLY USED MODELS OF COASTAL PROCESSES THROUGHOUT EUROPE 170 ANNEX 2 - OVERVIEW OF COASTAL EROSION MANAGEMENT TECHNIQUES 173 ANNEX 3 - OVERVIEW OF MONITORING TECHNIQUES COMMONLY US ED IN EUROPE 175 - 3 - INTRODUCTION This Shoreline Management Guide has been undertaken in the framework of the service contract B4-3301/2001/329175/MAR/B3 “Coastal erosion – Evaluation of the needs for action” signed between the Directorate General Environment of the European Commission and the National Institute of Coastal and Marine Management of the Netherlands (RIKZ).
    [Show full text]
  • Sand Beach Nourishment: Experience from the Mediterranean Coast of Israel
    Journal of Marine Science and Engineering Article Sand Beach Nourishment: Experience from the Mediterranean Coast of Israel Menashe Bitan 1 and Dov Zviely 2,* 1 Department of Maritime Civilizations, The Leon H. Charney School for Marine Sciences, University of Haifa, 199 Aba-Khoushi Avenue, Mount Carmel, Haifa 3498838, Israel; [email protected] 2 Faculty of Marine Sciences, Ruppin Academic Center, Emek-Hefer 40250, Israel * Correspondence: [email protected]; Tel.: +972-52-5805-758 Received: 21 March 2020; Accepted: 7 April 2020; Published: 10 April 2020 Abstract: Beach nourishment along the Mediterranean coast of Israel represents a new approach to mitigate coastal erosion by adding suitable sand to threatened beaches. This ‘soft’ solution has become more environmentally and economically acceptable than traditional ‘hard’ solutions, such as seawalls, revetments, detached breakwaters and groins. Beach nourishment projects have been implemented on the Israeli coast north of Ashdod Port (2011), north of Ashkelon Marina (2015) and in the south of Haifa Bay (2016–2017). The performance of these projects was analyzed and compared with nourishment projects along the Mediterranean beaches of Italy, France and Spain. Despite a lack of detailed documentation on most of the European nourishment projects, they proved more durable than the Israeli projects, which were compromised when the imported sand eventually washed offshore. Key factor for the Israeli projects’ failure include the unsuitable morphology of the beaches; insufficient unit sand volume (m3/m—volume of nourished sand per meter of the beach length); and imported sand that was too fine versus native sand. The unique physical conditions of the Israeli coast specifically, its open shelf and straight coastline subject to relatively high waves with a very long fetch—also contributed to the poor durability of the nourishment.
    [Show full text]
  • Cliff Stabilization
    Climate Change Adaptation Technologies for Water A practitioner’s guide to adaptation technologies for increased water sector resilience WATER ADAPTATION TECHNOLOGY BRIEF Cliff stabilization Challenge: Sea level rise Adaptation response: Green infrastructure for shoreline protection Description Cliff stabilization relates to measures carried out to minimize erosion of sloping soft rock coasts. The coasts are susceptible to erosion due to their relatively loose sediment, which is vulnerable to erosive forces such as waves, wind, tides, near-shore currents, storms and sea level rise. Cliff stabilization measures may take a wide variety of forms, including foot traffic protection, re-grading, smoothing, increasing vegetative cover and improving drainage. It can be implemented alongside various soft and hard coastal management measures. Cliff stabilization can be a useful option in densely populated areas with high value properties and infrastructure built on sloping soft rock coasts. Cliff stabilization can thus prevent erosion of valuable land and maintain the current coastline. Implementation Cliff stabilization addresses foot and slope erosion fro, targeting geo-technical instability and subsequent sliding/collapse of the slope. A number of measures may be taken to address these issues, including: Construction of revetments at the cliff foot; artificial smoothing or re-grading of the slope; smoothing the slope by filling it with granular material at the foot of the cliff; establishing vegetative cliff cover to protect against weathering and groundwater seepage; groundwater drainage to prevent the cliff from sliding due to high water pressure; and slope reinforcement through the use of piles to transfer load to an intact geological under layer. Addressing foreshore erosion through hard or soft coastal protection measures is also an integral component of cliff stabilization.
    [Show full text]
  • Coastal Protection with Respect to Climate Change and a Practical
    Coastal protection with respect to climate change. Practical application on the Belgian coast Trabajo final de Máster Master en transportes, territorio y urbanismo E.T.S. De ing. De caminos, canales y puertos Universitat politecnica de Valencia This master thesis is sumitted to achieve to degree of master of science in Industrial Sciences at KULeuven: industriële wetenschappen Bouwkunde Nicholas Van den Broeck Promotor: Professor Vicent de Esteban Chapapria Academic year 2016-2017 Table of contents List of figures ................................................................................................................................. 4 List of tables .................................................................................................................................. 5 Frequently used parameters ......................................................................................................... 6 Acknowledgements ....................................................................................................................... 7 Abstract ......................................................................................................................................... 8 Resumen ........................................................................................................................................ 9 1 Introduction ........................................................................................................................ 10 2 Coastal landforms...............................................................................................................
    [Show full text]