A cay (/ˈk, ˈk/ KEE, KAY), also spelled caye or key, is a small, low-elevation, sandy island on the surface of a coral reef. Cays occur in tropical environments throughout the Pacific, Atlantic, and Indian oceans, including in the Caribbean and on the Great Barrier Reef and Belize Barrier Reef.

Etymology

The Taíno word for "island", cairi, became cayo in Spanish and "cay" /ˈk/ in English (spelled "key" in American English).[1][2][3]

Formation and composition

Cay sand under an optical microscope

A cay forms when ocean currents transport loose sediment across the surface of a reef to where the current slows or converges with another current, releasing its sediment load. Gradually, layers of deposited sediment build up on the reef surface – a depositional node.[4][5] Such nodes occur in windward or leeward areas of reefs, where flat surfaces sometimes rise around an emergent outcrop of old reef or beach rock.

The island resulting from sediment accumulation is made up almost entirely of the skeletal remains of plants and animals – biogenic sediment – from the surrounding reef ecosystems.[6] If the accumulated sediments are predominantly sand, then the island is called a cay; if they are predominantly gravel, the island is called a motu.

Cay sediments are largely composed of calcium carbonate (CaCO3), primarily of aragonite, calcite, and high-magnesium calcite. They are produced by myriad plants (e.g., coralline algae, species of the green algae Halimeda) and animals (e.g., coral, molluscs, foraminifera). Small amounts of silicate sediment are also contributed by sponges and other creatures.[7][8][9][10] Over time, soil and vegetation may develop on a cay surface, assisted by the deposition of sea bird guano.

Development and stability

A range of physical, biological and chemical influences determines the ongoing development or erosion of cay environments. These influences include:

  • the extent of reef surface sand accumulations,
  • changes in ocean waves, currents, tides, sea levels, and weather conditions,
  • the shape of the underlying reef,
  • the types and abundance of carbonate producing biota and other organisms such as binders, bioeroders, and bioturbators (creatures that bind, erode, and mix sediments) living in surrounding reef ecosystems.[11][12]

Significant changes in cays and their surrounding ecosystems can result from natural phenomena such as severe El Niño–Southern Oscillation (ENSO) cycles. Also, tropical cyclones can either help build up or tear down these islands.[13][14]

There is much debate and concern over the future stability of cays in the face of growing human populations and pressures on reef ecosystems, and predicted climate changes and sea level rise.[15][16] There is also debate around whether these islands are relict features that effectively stopped expanding two thousand years ago during the late Holocene or, as recent research suggests, they are still growing, with significant new accumulation of reef sediments.[17]

Understanding the potential for change in the sediment sources and supply of cay beaches with environmental change is an important key to predicting their stability. Despite, or perhaps because of, all the debate around the future of cays there is consensus that these island environments are very complex and fairly fragile.

Examples

Examples of cays include:

See also

References

  1. Albury, Paul (1975). The Story of the Bahamas. MacMillan Caribbean. pp. 5, 13–14. ISBN 0-333-17131-4.
  2. Craton, Michael (1986). A History of the Bahamas. San Salvador Press. p. 17. ISBN 0-9692568-0-9.
  3. Keegan, William F. (1992). The People Who Discovered Columbus: The Prehistory of the Bahamas. University Press of Florida. p. 11. ISBN 0-8130-1137-X.
  4. Hopley, D. (1981). "Sediment movement around a coral cay, Great Barrier Reef, Australia". Pacific Geology. 15: 17–36.
  5. Gourlay, M.R. (1988). "Coral cays: Products of wave action and geological processes in a biogenic environment". In Choat, J.H.; et al. (eds.). Proceedings of the 6th International Coral Reef Symposium: Vol. 2: Contributed Papers. Townsville, Australia. pp. 497–502.
  6. 1 2 Hopley, D. (1982). The Geomorphology of the Great Barrier Reef – Quaternary Development of Coral Reefs. Wiley-Interscience Publication. New York, NY: John Wiley and Sons Ltd. ISBN 0471045624.
  7. Chave, K. (1964). "Skeletal durability and preservation". In Imbrie, J.; Newell, N. (eds.). Approaches to Palaeoecology. Sydney, AU: John Wiley and Sons Inc.
  8. Folk, R.; Robles, P. (1964). "Carbonate sands of Isla Perez, Alacran Reef Complex, Yucatan". Journal of Geology. 72 (3): 255–292. doi:10.1086/626986. JSTOR 30075161. S2CID 129407952.
  9. Scoffin, T.P. (1987). Introduction to Carbonate Sediments and Rocks. Glasgow, UK: Blackwell. ISBN 0216917891.
  10. Yamano, H.; Miyajima, T.; Koike, I. (2000). "Importance of foraminifera for the formation and maintenance of a coral sand cay: Green Island, Australia". Coral Reefs. 19: 51–58. doi:10.1007/s003380050226. S2CID 43843977.
  11. Harney, J.N.; Fletcher, C.H. (2003). "A budget of carbonate framework and sediment production, Kailua Bay, Oahu, Hawaii" (PDF). Journal of Sedimentary Research. 73 (6): 856–868. doi:10.1306/051503730856.
  12. Hart, D.E.; Kench, P.S. (2006). "Carbonate production of an emergent reef platform, Warraber Island, Torres Strait, Australia" (PDF). Coral Reefs. 26: 53–68. doi:10.1007/s00338-006-0168-8. hdl:10092/312. S2CID 11188232. Archived from the original (PDF) on 2017-04-07. Retrieved 2013-05-31.
  13. Scoffin, T.P. (1993). "The geological effects of hurricanes on coral reefs and the interpretation of storm deposits". Coral Reefs. 12 (3–4): 203–221. doi:10.1007/BF00334480. S2CID 39658794.
  14. Woodroffe, C.D. (2003). Coasts: Form, Process and Evolution (PDF). Cambridge, UK: Cambridge University Press. ISBN 0521011833.
  15. Kench, P.S.; Cowell, P. (2002). "Erosion of low-lying reef islands". Tiempo Climate Newswatch. 46: 6–12. Archived from the original on 2013-05-10.
  16. Hart, D.E. (2003). "The importance of sea-level in an inter-tidal reef platform system, Warraber Island, Torres Strait". Proceedings of the 22nd Biennial New Zealand Geographical Society Conference. Auckland, NZ. pp. 77–81.
  17. Woodroffe, C.D.; Samosorn, B.; Hua, Q.; Hart, D.E. (2007). "Incremental accretion of a sandy reef island over the past 3000 years indicated by component-specific radiocarbon dating". Geophysical Research Letters. 34 (3). CiteSeerX 10.1.1.548.8845. doi:10.1029/2006GL028875.
  18. McLean, R.; Stoddart, D. (1978). "Reef island sediments of the northern Great Barrier Reef". Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 291 (1378): 101. doi:10.1098/rsta.1978.0093. JSTOR 75221. S2CID 121541343.
  19. Woodroffe, C.D.; Kennedy, D.M.; Hopley, D.; Rasmussen, C.E; Smithers, S.G. (2000). "Holocene reef growth in Torres Strait". Marine Geology. 170 (3–4): 331–346. doi:10.1016/S0025-3227(00)00094-3.
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