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Land loss

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Summary table of the common physical and anthropogenic causes of coastal land loss.[1]

Land loss is the term typically used to refer to the conversion of coastal land to open water by natural processes and human activities. The term land loss includes coastal erosion. It is a much broader term than coastal erosion because land loss also includes land converted to open water around the edges of estuaries and interior bays and lakes and by subsidence of coastal plain wetlands. The most important causes of land loss in coastal plains are erosion, inadequate sediment supply to beaches and wetlands, subsidence, and global sea level rise. The mixture of processes responsible for most of the land loss will vary according to the specific part of a coastal plain being examined.[1][2] The definition of land loss does not include the loss of coastal lands to agricultural use, urbanization, or other development.[3]

Wetland loss

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Although seemingly related, wetland loss, is defined differently than land loss. Commonly, wetland loss is defined as the conversion of vegetated wetlands into either uplands or drained areas, unvegetated wetlands (e.g., mudflats), or (submerged habitats (open water). According to this, and similar definitions, wetland loss includes both land loss and land consumption as components of it. In historic times, both wetland and land loss typically are the result of a varying, often controversial mixture of natural and anthropogenic factors.[4][5] There are other definitions of wetland loss commonly used. For example, some researchers defined wetland loss as "the substantial removal of wetland from its ecologic role under natural conditions."[6]

Land loss mechanisms

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The main causes of land loss are coastal erosion, inadequate sediment supply, subsidence, and sea level rise. Coastal erosion occurs when the rate of sediment deposition is slower than the rate of sediment removal by coastal currents.[7] The most important cause of decreased rates of sediment deposition is the construction of dams and reservoirs although sediment control and conservation programs can also play a role.[8] Once a dam is constructed, sediment that previously traveled freely in the river is trapped in the reservoir. Decreased sediment loads downstream of the dam prevent sediment from replenishing the delta.[9] Subsidence is the compaction of soil resulting in a lower elevation. Subsidence can occur when oil, gas, or groundwater are extracted. These substances hold the land up until they are removed. Compaction due to heavy urban infrastructure also occurs.[10] Sea level rise due to climate change is another threat to coastal land.[11]

Land loss and deltas

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A simplified figure showing coastal erosion, sediment starvation, subsidence, and sea level rise, the main mechanisms causing delta land loss.

Because of a highly variable combination of sea level rise, sediment starvation, coastal erosion, wetland deterioration, subsidence, and various human activities, land loss within delta plains is a significant global problem.[1] The large delta plains of the world, including the Danube, Ganges, Brahmaputra, Indus, Mahanadi, Mangoky, McKenzie, Mississippi, Niger, Nile, Shatt el Arab, Volga, Yellow, Yukon, and Zambezi deltas, have all suffered significant land loss as the result of either coastal erosion, internal conversion of wetlands to open water, or a combination of both. For the 15 deltas studied by Coleman and others,[12] these deltas experienced a total irreversible land loss of 5,104 km2 (1,971 sq mi) of wetlands between the early 1980s and 2002. During this period, the total average land loss for all these deltas was about 41 km2 (16 sq mi) per year. In the case of the Mississippi River Delta, they found that in 12 years, some 253 km2 (98 sq mi) of wetlands had been converted to new open water at a rate of 21 km2 (8.1 sq mi) per year.[12] The factors contributing to land loss in the deltas below do not include the direct conversion of delta wetlands into agricultural or urban land, although this is happening concurrently in many of them.

  • The Danube Delta is located in Romania and Ukraine where the Danube River enters into the Black Sea. The loss of this delta is primarily due to sediment starvation caused by dams along the river. After the construction of the two largest of these dams, the Iron Gates dams, sediment in the river decreased by 60% - 70%.[13]
  • The Ganges Delta forms where the combined waters of the Ganges and Brahmaputra rivers enter the Bay of Bengal. The delta is damaged by sediment starvation due to the construction of many upstream dams. The location is also susceptible to sea level rise, with most of the delta below 5 m in elevation.[14]
  • The Mahanadi River Delta forms where the Mahanadi, Brahmani, and Baitarini rivers enter into the Bay of Bengal on the east coast of India. Similar to the Ganges River Delta, significant amounts of the Mahanadi Delta are below 5 m in elevation and are threatened by sea level rise. Dams for irrigation and flood control, including the Hirakud Dam, contribute to sediment starvation.[16] 65% of the coastline faces erosion.[17]
  • The Nile River Delta is formed by the Nile River flowing north through Egypt and entering into the Mediterranean Sea. The primary reason for Nile Delta loss is sediment entrapment behind the Aswan dams. Secondary reasons include subsidence, sea level rise, and strong coastal currents.[21]
  • The Shatt al-Arab River Delta is formed when the Shatt al-Arab River flows into the Persian Gulf. The river itself is formed by the joining of the Tigris and Euphrates rivers. A decrease in freshwater entering the river due to irrigation and, thus, a decrease in sediment load has increased coastal erosion of the delta. Hydraulic structures and sea level rise also play a role in the loss of the delta.[22]
  • The Volga Delta is formed when the Volga River enters into the Caspian Sea in Russia. It has gained land with the drop in the level of the Caspian Sea. As the water level has risen again in the last twenty years, the delta has still not experienced any loss. As the terms are defined above, the delta has experienced wetland loss but not land loss.[23]
  • The Yellow River Delta is formed as the Yellow River flows into the Yellow Sea. The Yellow River flows through the Loess Plateau and carries large amounts of sediment. Until 1998, the Yellow River Delta was expanding, but it has been decreasing ever since.[24] Many dams have been constructed on the Yellow River and are starving the coastline of sediment.[25]
  • The Yukon River Delta is formed when the Yukon and Kuskokwim rivers enter into the Bering Sea in Alaska. The delta is threatened by sea level rise; an increase of 0.5 m would increase erosion due to higher tides. Inactive floodplains where tides and sedimentation rates are not in equilibrium are most at risk.[26]
  • The Zambezi River Delta is formed when the Zambezi River enters the Mozambique Channel off of the east coast of Africa. The construction of the Kariba Dam, the Cahora Bassa Dam, and dykes have altered natural flooding and sediment deposition. The delta coast is in a state of erosion due to sediment starvation and a slowly rising sea level.[27]

See also

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References

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  1. ^ a b c Morton, R.A., 2003. An overview of coastal land loss: with emphasis on the Southeastern United States. Open-File report 03-337. US Geological Survey, Center for Coastal and Watershed Studies, St. Petersburg, Florida. 28 pp.
  2. ^ Britsch, L.D. and Kemp III, E.B., 1990. Land loss rates: Mississippi River deltaic plain. Technical Report no. WES/TR/GL-90-2. Geotechnical Lab, Army Waterways Experiment Station, Vicksburg, Mississippi.
  3. ^ Barras, J.A., P.E. Bourgeois, and L.R. Handley. 1994. Land loss in coastal Louisiana 1956-90. National Biological Survey, National Wetlands Research Center Open File Report 94-01. 4 pp.
  4. ^ Boesch, D.F., Josselyn, M.N., Mehta, A.J., Morris, J.T., Nuttle, W.K., Simenstad, C.A. and Swift, D.J., 1994. Scientific assessment of coastal wetland loss, restoration and management in Louisiana. Journal of Coastal Research, Special Issue No. 20, pp.1-103.
  5. ^ Chan, A.W. and Zoback, M.D., 2007. The role of hydrocarbon production on land subsidence and fault reactivation in the Louisiana coastal zone. Journal of Coastal Research, 23(3) pp.771-786.
  6. ^ Craig, N.J., Turner, R.E. and Day, J.W., 1979. Land loss in coastal Louisiana (USA). Environmental Management, 3(2), pp.133-144.
  7. ^ McManus, John., 2002. "Deltaic responses to changes in river regimes." "Marine Chemistry", 79(3-4) pp. 155-170.
  8. ^ Walling, D.E. and Fang, D., 2003. "Recent trends in the suspended sediment loads of the world's rivers." "Global and Planetary Change", 39(1-2), pp. 111-126.
  9. ^ Kondolf, G. Mathias, et al., 2014. "Sustainable sediment management in reservoirs and regulated rivers: Experiences from five continents." "Earth's Future", 2(5), pp. 256-280.
  10. ^ Schmidt, Charles W., 2015. "Delta Subsidence: An Imminent Threat to Coastal Populations." "Environmental Health Perspectives", 123(8), pp. 204-209.
  11. ^ Ericson, Jason P. et al., 2006. "Effective sea-level rise and deltas: Causes of change and human dimension implications." "Global and Planetary Change", 50, pp. 63-82.
  12. ^ a b Coleman, J.M., Huh, O.K. and Braud Jr, D., 2008. Wetland loss in world deltas. Journal of Coastal Research, 24(sp1), pp. 1-14.
  13. ^ Panin, Nicolae and Jipa, Dan C., 2002. "Danube River Sediment Input and its Interaction with the North-western Black Sea." "Estuarine Coastal and Shelf Science", 54(3), pp. 551-562.
  14. ^ Rahman, M.M. et al., 2020. "Ganges-Brahmaputra-Meghna Delta, Bangladesh and India: A Transnational Mega-Delta." "Deltas in the Anthropocene", pp. 23-51.
  15. ^ Memon, Altaf A., 2005. "Devastation of the Indus River Delta." "World Water and Environmental Resources Congress 2005".
  16. ^ Hazra, Sugata et al., 2020. "The Mahanadi Delta: A Rapidly Developing Delta in India." "Deltas in the Anthropocene", pp. 53-77.
  17. ^ Mukhopadhyay, Anirban et al., 2018. "Threats to coastal communities of Mahanadi delta due to imminent consequences of erosion – Present and near future." "Science of the Total Environment", 6337-638, pp. 717-729.
  18. ^ Rakotomavo, Andriamparany and Fromard, François., 2010. "Dynamics of mangrove forests in the Mangoky River delta, Madagascar, under the influence of natural and human factors." "Forest Ecology and Management", 259(6), pp. 1161-1169.
  19. ^ Liu, Lin, Zhang, Tingjun and Wahr, John., 2010. "InSAR measurements of surface deformation over permafrost on the North Slope of Alaska." "Journal of Geophysical Research: Earth Surface", 115(F3).
  20. ^ Uluocha, N.O. and Okeke, I.C., 2004. "Implications of wetlands degradation for water resources management: Lessons from Nigeria." "GeoJournal", 61, pp. 151-154.
  21. ^ Stanley, Daniel Jean., 1996. "Nile delta: extreme case of sediment entrapment on a delta plain and consequent coastal land loss." "Marine Geology", 129(3-4), pp.189-195.
  22. ^ Al-Aesawi, Qassim, Al-Nasrawi, Ali K. M. and Jones, Brian G., 2020. "Short-term Geoinformatics Evaluation in the Shatt Al-Arab Delta (Northwestern Arabian/Persian Gulf)." "Journal of Coastal Research", 36(3), pp. 498-505.
  23. ^ Li, C. et al., 2009. "Development of the Volga Delta in Response to Caspian Sea-Level Fluctuation during Last 100 Years." "Journal of Coastal Research", 20, pp. 401-414.
  24. ^ Gao, Peng et al., 2018. "Land degradation changes in the Yellow River Delta and its response to the streamflow‐sediment fluxes since 1976." "Land Degradation & Development", 29(9), pp. 3212-3220.
  25. ^ Wang, Houjie and Bi, Naishuang., 2015. The sediment-starved Yellow River Delta as remotely controlled by human activities in the river basin." "American Geophysical Union, Fall Meeting 2015".
  26. ^ Jorgenson, Torre and Ely, Craig., 2001. "Topography and Flooding of Coastal Ecosystems on the Yukon-Kuskokwim Delta, Alaska: Implications for Sea-Level Rise." "Journal of Coastal Research", 17(1), pp. 124-136.
  27. ^ Beilfuss, Richard, Dutton, Paul and Moore, Dorn., 2000. "Land Cover and Land Use Change in the Zambezi Delta." "Biodiversity of Zambezi Basin Wetlands", vol 3, ch 2, pp. 31-105.