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Environmental Earth Sciences

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01.08.2015 | Original Article

Assessment of Egypt’s Red Sea coastal sensitivity to climate change

verfasst von: Mohamed E. Hereher

Erschienen in: Environmental Earth Sciences | Ausgabe 4/2015

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Abstract

A coastal sensitivity index (CSI) was developed to assess the response of the Red Sea coast in Egypt to climate change in terms of sea level rise and global warming. Six different variables pertaining to the intrinsic characteristics of the coast that extends to 1200 km were utilized, notably: coastal geomorphology, coastal slope, width of the coastal plain, shoreline exposure, fauna/flora and land use. Data have been extracted, manipulated and presented using remote sensing and GIS analysis. The resulting coastal sensitivity map depicts the susceptibility levels of the Red Sea coastal plain to climate change. The most severely sensitive segments (very high CSI) account for 31 % (365 km) of the coast. They occur across unconsolidated, flat, wide, exposed, ecologically effective and/or inhabited coasts. On the other hand, the least sensitive (low CSI) coastal segments total 245 km (20 %) and are mainly rocky, steep, narrow, barren and/or inaccessible shores. Eustatic sea level rise by 1 m should inundate a coastal area of 106 km², whereas a sudden tsunami of 5 m height should overwhelm 724 km², particularly at the southern section near Shalateen. Global warming of seawater should impact the coastal zone between Hurghada and Marsa Alam (270 km long) due to the occurrence of fringing coral reef systems. The coastal sensitivity index provides a synoptic overview that could help prioritize emergency plans and protection strategies to reduce the ramifications of climate change.

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Abdel-Kader A, El-Raey M, Nasr M, El-Gamily H (1998) Environmental sensitivity analysis of potential oil spill for Ras Mohammed coastal zone, Egypt. J Coastal Res 14:502–510

Abu Al-Izz M (1971) Landforms of Egypt. The American University in Cairo Press, p 281

Abuodha P, Woodroffe C (2010) Assessing vulnerability to sea-level rise using a coastal sensitivity index: a case study from southeast Australia. J Coast Conserv 14:189–205CrossRef

Al-shalabi M, Billa L, Pradhan B, Mansor S, Al-Sharif AA (2013) Modelling urban growth evolution and land-use changes using GIS based cellular automata and SLEUTH models: the case of Sana’a metropolitan city, Yemen. Environ Earth Sci 70(1):425–437CrossRef

Arnott RD (2010) Introduction to coastal processes and geomorphology. Cambridge University Press, NY, p 442

Arnous M, Aboulela H, Green D (2011) Geo-environmental hazards assessment of the north western Gulf of Suez, Egypt. J Coast Conserv 15:37–50CrossRef

Bathrellos GD, Papanastassiou KG, Skilodimou HD, Papanastassiou D, Chousianitis KG (2012) Potential suitability for urban planning and industry development using natural hazard maps and geological–geomorphological parameters. Environ Earth Sci 66:537–548CrossRef

Bathrellos GD, Papanastassiou KG, Skilodimou HD, Skianis GA, Chousianitis KG (2013) Assessment of rural community and agricultural development using geomorphological–geological factors and GIS in the Trikala prefecture (Central Greece). Stoch Environ Res Risk Assess 27(2):573–588CrossRef

Boruff BJ, Emrich C, Cutter SL (2005) Erosion hazard vulnerability of US coastal counties. J Coastal Res 21:932–943CrossRef

Cantin NE, Cohen AL, Karnauskas KB, Tarrant AM, McCorkle DC (2010) Ocean warming slows coral growth in the central Red Sea. Science 329(5989):322–325CrossRef

Caragnano A, Colombo F, Rodondi G, Basso D (2009) 3-D distribution of nongeniculate corallinales: a case study from a reef crest of South Sinai (Red Sea, Egypt). Coral Reefs 28(4):881–891CrossRef

Chaaban F, Darwishe H, Louche B, Queney YB, Masson E, El Khattabi J, Carlier E (2012) Geographical information system approach for environmental management in coastal area (Hardelot-Plage, France). Environ Earth Sci 65:183–193CrossRef

Churchill J, Lentz S, Farrar J, Abualnaja Y (2014) Properties of Red Sea coastal currents. Continental Shelf Res 78:51–61CrossRef

Coles SL, Brown BE (2003) Coral bleaching: capacity for acclimatization and adaptation. Adv Mar Biol 46:183–223CrossRef

Collingham YC, Huntley B (2000) Impacts of habitat fragmentation and patch size upon migration rates. Ecol Appl 10:131–144CrossRef

Davis R (1996) Coasts. Prentice Hall, Upper Saddle

Doukakis E (2005) Coastal vulnerability and risk parameters. European Water 11(12):3–7

Duriyapong F, Nakhapakorn K (2011) Coastal vulnerability assessment: a case study of Samut Sakhon coastal zone. Songklanakarin J Sci Technol 33:469–476

El Moursi M, Hoang C, El Fayoumy I, Hegab O, Faure H (1994) Pleistocene evolution of the Red Sea coastal plain, Egypt: evidence from uranium-series dating of emerged reef terraces. Quat Sci Rev 13:345–359CrossRef

Finkl C (2004) Coastal classification: systematic approaches to consider in the development of a comprehensive scheme. J Coast Res 20:166–213CrossRef

Finkl C, Pelinovsky E, Cathcar R (2012) A review of potential tsunami impacts to the Suez Canal. J Coast Res 28:745–759CrossRef

Frihy O, El Ganaini M, El Sayed W, Iskander M (2004) The role of fringing coral reef in beach protection of Hurghada, Gulf of Suez, Red Sea of Egypt. Ecol Eng 22:17–25CrossRef

Frihy O, Hassan A, El Sayed W, Iskandera M, Sherif M (2006) A review of methods for constructing coastal recreational facilities in Egypt (Red Sea). Ecol Eng 27:1–12CrossRef

Hammar-Klose ES, Pendleton EA, Thieler ER, Williams SJ (2003) Coastal vulnerability assessment of Cape Cod national seashore (CACO) to sea-level rise, US Geological Survey, Open file Report 02–233

Hereher M (2010) Vulnerability of the Nile Delta to sea level rise: an assessment using remote sensing. Geomat Nat Hazards Risk 1:315–321CrossRef

Hereher M (2014) Assessment of South Sinai Coastal vulnerability to climate change. J Coast Res. doi:10.2112/JCOASTRES-D-14-00018.1

Hereher M (2015) Coastal vulnerability assessment for Egypt’s Mediterranean coast. Geomat Nat Hazards Risk 6(4):342–355CrossRef

Hereher M, El-Ezaby K (2012) Soil and water quality assessment along the Red Sea coast, Egypt. Int J Environ Stud 69(1):65–77CrossRef

Hughes TP, Baird AH, Bellwood DR, Card M, Connolly SR, Folke C, Hoegh Grosberg R, Guldberg O, Jackson JC, Kleypas J, Lough JM, Marshall P, Nystrom M, Palumbi SR, Pandolfi JM, Rosen B, Roughgarden J (2003) Climate change, human impacts, and the resilience of coral reefs. Science 301:929–933CrossRef

IPCC (Intergovernmental Panel on Climate Change) (2001) Climate change 2001. The scientific basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. In: Houghton JT, Ding Y, Griggs DJ, Noguer, M, van der Linden PJ, Dai X, Maskell K, Johnson CA (eds) Cambridge University Press, Cambridge, New York, p 881

Johnston A, Slovinsky P, Yates K (2014) Assessing the vulnerability of coastal infrastructure to sea level rise using multi-criteria analysis in Scarborough, Maine (USA). Ocean Coast Manag 95:176–188CrossRef

Kleypas JA, Buddemeier RW, Archer D, Gattuso JP, Langdon C, Opdyke BN (1999) Geochemical consequences of increased atmospheric carbon dioxide on coral reefs. Science 284(5411):118–120CrossRef

Kumar TS, Mahendra RS, Nayak S, Radhakrishnan K, Sahu KC (2010) Coastal vulnerability assessment for Orissa State, East Coast of India. J Coast Res 26(3):523–534CrossRef

Kunte PD, Jauhari N, Mehrotra U, Kotha M, Hursthouse AS, Gagnon AS (2014) Multi-hazards coastal vulnerability assessment of Goa, India using geospatial techniques. Ocean Coast Manag 95:264–281CrossRef

McWilliams JP, Cote IM, Gill JA, Sutherland WJ, Watkinson A (2005) Accelerating impacts of temperature-induced coral bleaching in the Caribbean. Ecol 86(8):2055–2060CrossRef

Meehl GA, Washington WM, Collins WD, Arblaster JM, Hu A, Buja LE, Strand WG, Ten H (2005) How much more global warming and sea level rise. Science 307:1769–1772CrossRef

Nicholls RJ (2002) Analysis of global impacts of sea-level rise: a case study of flooding. Phys Chem Earth 27(32–34):1455–1466CrossRef

Ozyurt G, Ergin A (2010) Improving coastal vulnerability assessments to sea-level rise: a new indicator-based methodologyfor decision makers. J Coast Res 26(2):265–273CrossRef

Papadopoulou-Vrynioti K, Bathrellos GD, Skilodimou HD, Kaviris G, Makropoulos K (2013) Karst collapse susceptibility mapping considering peak ground acceleration in a rapidly growing urban area. Eng Geol 158:77–88CrossRef

Pendleton EA, Thieler ER and Williams SJ (2004) Coastal vulnerability assessment of Cap Hettaras national seashore (CAHA) to sea level rise. US Geological Survey Open-File Report 2004–1064

Pendleton EA, Thieler ER and Williams SJ (2005) Coastal vulnerability assessment of Golden Gate national recreation area to sea-level rise. US Geological Survey Open-File Report 2005–1058, p 27

Plaziat J, Baltzer F, Choukri A, Conchon O, Freytet F (1995) Quaternary changes in the Egyptian shoreline of the northwestern Red Sea and Gulf of Suez. Quat Int 29(30):11–22CrossRef

Rao KN, Subraelu P, Rao T, Malini B, Ratheesh R, Bhatta-charya S, Rajawat A (2008) Sea-level rise and coastal vulnerability: an assessment of Andhra Pradesh coast, India through remote sensing and GIS. J Coast Conserv 12(4):195–207CrossRef

Reefbase (2013) Reefbase—a global information system for coral reefs. http://www.reefbase.org

Saad A (2010) Wave and wind conditions in the Red Sea—a numerical study using a third generation wave model. M.Sc. Thesis in Physical Oceanography. Geophysical Institute, University of Bergen, Norway, p 88

Said R (1962) The geology of Egypt. Elsevier, New York, p 377

Salem S (2009) Paleo-tsunami deposits on the Red Sea beach, Egypt. Arab J Geosci 2:185–197CrossRef

Skilodimou HD, Stefouli M, Bathrellos GD (2002) Spatio-temporal analysis of the coastline of Faliro Bay, Attica, Greece. Estud Geol Madrid 58(3–4):83–89

Small C, Nicholls RJ (2003) A global analysis of human settlement in coastal zones. J Coast Res 19(3):584–599

Thieler ER, Hammar-Klose ES (1999) National assessment of coastal vulnerability to sea-level rise: preliminary results for the US Atlantic Coast US Geological Survey, Open-File Report 99–593, 1 sheet

Uddameri V, Singaraju S, Hernandez EA (2014) Impacts of sea-level rise and urbanization on groundwater availability and sustainability of coastal communities in semi-arid South Texas. Environ Earth Sci 71(6):2503–2515CrossRef

Williams S (2013) Sea-level rise implications for coastal regions. J Coastal Res 63:184–196CrossRef

Wolfenden E, Ebinger C, Yirgu G, Deino A, Ayele D (2004) Evolution of the northern main Ethiopian Rift: birth of a triple junction. Earth Planet Sci Lett 224:213–228CrossRef

Youssef AM, Maerz NH (2013) Overview of some geological hazards in the Saudi Arabia. Environ Earth Sci 70(7):3115–3130CrossRef

Zahran M, Willis A (2009) The vegetation of Egypt. Springer Science Bus Media, Berlin, p 437

Titel: Assessment of Egypt’s Red Sea coastal sensitivity to climate change
verfasst von: Mohamed E. Hereher
Publikationsdatum: 01.08.2015
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 4/2015
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-015-4304-z

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