Blue hole

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Short description: Marine cavern or sinkhole, open to the surface, in carbonate bedrock
The Great Blue Hole, located near Ambergris Caye, Belize
Dean's Blue Hole, Long Island, Bahamas
Watling's Blue Hole, San Salvador Island, Bahamas

A blue hole is a large marine cavern or sinkhole, which is open to the surface and has developed in a bank or island composed of a carbonate bedrock (limestone or coral reef). Blue holes typically contain tidally influenced water of fresh, marine, or mixed chemistry. They extend below sea level for most of their depth and may provide access to submerged cave passages.[1] Well-known examples are the Dragon Hole (in the South China Sea) and, in the Caribbean, the Great Blue Hole and Dean's Blue Hole.

Blue holes are distinguished from cenotes in that the latter are inland voids usually containing fresh groundwater rather than seawater.

Description

Blue holes are roughly circular, steep-walled depressions, and so named for the dramatic contrast between the dark blue, deep waters of their depths and the lighter blue of the shallows around them. Their water circulation is poor, and they are commonly anoxic below a certain depth; this environment is unfavorable for most sea life, but nonetheless can support large numbers of bacteria.[2] The deep blue color is caused by the high transparency of water and bright white carbonate sand. Blue light is the most enduring part of the spectrum; other parts of the spectrum—red, yellow, and finally green—are absorbed during their path through water, but blue light manages to reach the white sand and return upon reflection.

The deepest blue hole in the world at 300.89 meters (987 feet) deep is in the South China Sea and is named the Dragon Hole, or Longdong.[3] The second deepest blue hole in the world with underwater entrance at 202 metres (663 ft) is Dean's Blue Hole, located in a bay west of Clarence Town on Long Island, Bahamas. Other blue holes are about half that depth at around 100–120 metres (330–390 ft). The diameter of the top entrance ranges typically from 25–35 metres (82–115 ft) (Dean's Blue Hole) to 300 metres (980 ft) (Great Blue Hole in Belize).

The overall largest blue hole (taking into account depth and width) is located 100 kilometers from the coast of Belize. The Great Blue Hole is a massive 300 meters wide and 125 meters deep.[4]

Formation

Blue holes formed during past ice ages, when the sea level was as low as 100–120 metres (330–390 ft) lower than at present.[5] At those times, these formations were targets of the same erosion from rain and chemical weathering common in all limestone-rich terrains; this ended once they were submerged at the end of the ice age.

Most blue holes contain freshwater and saltwater. The halocline is the point in these blue holes where the freshwater meets the saltwater and where a corrosive reaction takes place that eats away at the rock.[6] Over time this can create side passages, or horizontal "arms", that extend from the vertical cave. These side passages can be quite long; e.g., over 600 metres (2,000 ft) in the case of the Sawmill Sink in the Bahamas.

The means in which blue holes are formed is through Karst processes. Karst processes need a specific type of topography. Rocks like limestone, gypsum and marble are soluble and so dissolution creates passages and cave systems underground. This paired with doline formation allows blue holes to be formed. Doline formation were once closed depressions formed by solution of superficial rock or subsidence collapse into an underground void.

Most blue holes are formed through these processes, however, some show no signs of passages or cave systems which are requirements of karst and doline processes. Therefore, these blue holes must have other origins like possibly vertical reef development.[7]

Some blue holes however do not experience karst or doline processes during their formation. Some form through bedrock dissolution and collapse[8] which in this case usually is controlled through tidal forcing, while others are controlled by carbonate dissolution, sea level fluctuations, and the presence of eogenetic carbonates.[8]

Occurrence

Blue holes are typically found on shallow carbonate platforms, exemplified by the Bahama Banks, as well as on and around the Yucatán Peninsula, such as at the Great Blue Hole at Lighthouse Reef Atoll, Belize.

Many deep spring basins formed by karst processes and located inland also are called blue holes, for example, Blue Hole in Castalia, Ohio.

Diversity

Many different fossils have been discovered that indicate the type of life forms that existed in blue holes. Other life forms such as marine life and marine fossils have also been noticed; crocodile and tortoise fossils,[9] for instance, have been found in blue holes. Important types of bacterial colonies have also been found in blue holes. Due to the conditions of a blue hole, they are forced to live off sulfur compounds like hydrogen sulfide, which are toxic to most organisms.[5] These special bacteria have produced many insights into the chemistry and biology of microbial life.

Blue holes have a great diversity of microbes. They create biogeochemical pathways creating a unique and diverse environment within the blue holes. In the surface layer, oxygen, DOC, POC and chlorophyll need to be in low levels in order for cyanobacteria to respire.[10] As depth increases, many branches and sub branches of microbes create specific niches based on the chemistry and nutrient availability of that depth.[10]

Microorganisms including foraminifera, meiobenthic, and nematodes also follow this pattern of organization, and inhabit the areas of the water column where the nutrients they rely on are most available. Nematodes, which are predominantly non-selective detrivores, are tolerable to the anoxic conditions at the base of blue holes, allowing them to survive where other species cannot. They thrive at the lowest depths of blue holes due to the abundance of organic matter that settles there. Similarly, foraminifera inhabit the lower depths, and even increase in diversity with depth. Meiobenthic organisms cannot survive the high sulfide found at depth, and remain in the surface layers of blue holes. Generally, the diversity of all forms of life is 2-3x greater in blue holes than other diverse areas of the ocean, including coastal and abyssal environments. When the diversity of microorganisms is larger, a proportional increase in larger organisms and their diversity is to be expected.

Sedimentation

Sediment accumulation is quite unique in blue holes. Sedimentation occurs at the center of holes rather than the edges.[11] There are many different kinds of sediment that help preserve fossils and climate records. Main sediments that build up and create layers in blue holes are sapropel, detrital peat and lacustrine marls. Within these layers, microfossils can be found.

Sediment cores taken from three blue holes in the Bahamas showed that with depth, more sapropel, detrital and freshwater peat, and lacustrine marls were found. At about 150 cm of sediment core, microfossils of wood, Charophytes and Hydrobiidae were found.

Chemistry

The chemistry of blue holes vary greatly depending on how they were formed. All blue holes have a layer of freshwater at the surface and more saline water as the depth increases. Many have pycnoclines and haloclines that show these zones, similar to the ocean around it.[12] Many blue holes are great sediment traps and can preserve climate and fossil records dating back to the last glacial maximum.[11] The reason blue holes are able to preserve such records is due to the anoxic bottom water most blue holes contain. Stable Hydrogen and Oxygen isotopes can be used to help identify where the water within blue holes comes from. Scientists have discovered that many have meteoric or marine sources of saline water within them.[8] Being able to identify where the water comes from in these columns allows scientists to see how tidally influenced they are.[8] Most blue holes have a range in salinity from fresh water to hypersaline. Conduits and passageways allow for brackish water to enter as well. When the same isotopes of major ions are found in blue holes and in the surrounding ocean, it can be concluded that these blue holes are tidally influenced and have a marine water source, however, if the isotopes are similar to those found in meteoric lenses, then the source is meteoric.[8]

Preservation

Due to water conditions at the bottom of blue holes, fossil preservation is very effective. Insufficient oxygen and light prevent decay; these conditions have resulted in preservation of fossils for thousands of years, allowing scientists to identify the skeletons of species extinct for years, as well as human skeletons. Sediments surrounding the fossils are rich in macro and microfossils (twigs, leaves, pollen, spores, etc.), further improving their preservation.

Fossils identified:

  • Tortoise (undescribed species)
  • Caracara (Caracara creightoni)
  • Cuban crocodile (Crocodylus gundlachii)
  • Cooper's Hawk (Accipiter cooperii)
  • Birds (25 species)
  • Snakes (3 species)
  • Bats (4 species)
  • Ancient Native Lucayans

Plant fossils are also well preserved at the bottom of blue holes, and using sediment cores it is possible to determine what species of plants and trees existed around the area thousands of years ago. For example, The Bahamas today are dominated by tropical dry evergreens, and tropical pines, but sediment cores from the Abacos blue hole revealed preserved woody species, such as Coccoloba, Exothea, and Bursera.

Expeditions

Exploring blue holes requires a level of competence and equipment appropriate to the depth and overhead penetration. In 2009 a team of scientists set out to study seven of these blue holes in the Bahamas.[13] Through over 150 dives, the scientists, led by Keith Tinker, investigated bacteria able to live in anoxic environments.[13] This allowed them to make connections to fields such as astrobiology where organisms thrive without oxygen or sunlight.

In 2018, another group of scientists set out to explore the Great Blue Hole of Belize using two submarines of the latest technology. One of the major scientific contributions to result from this expedition was the first 3-dimensional map of its interior.[4] The researchers captured features such as stalactites, the hydrogen sulfide layer, and other details that cannot usually be seen by the naked human eye.

As part of a three-year study, a group of scientists set out in May and September 2019 to explore a blue hole nicknamed the "Amberjack Hole" located 30 miles off the coast of Sarasota, Florida. Individuals from Mote Marine Laboratory, Florida Atlantic University, Harbor Branch, Georgia Institute of Technology, the United States Geological Survey, and the NOAA Office of Ocean Exploration participated in the expedition. The expedition gathered information about life around and within the hole, seawater composition, and the hole's bottom sediments. A follow-up expedition is planned in August 2020 to a deeper blue hole named the "Green Banana" off the coast of Florida.[14][15][16]

In contrast to the various successful expeditions completed, many explorers have perished in their attempts to reach the bottom of a blue hole. The Red Sea Blue Hole located in Egypt is nicknamed the "Divers' Cemetery" because at least 40 divers have died there.[17]

Diving risks

Despite the beauty and allure of blue holes, they are some of the most dangerous waters to dive. Nitrogen narcosis begins to set in at depths below 20 m (70 ft) and causes disorientation and changes in consciousness. Divers experiencing nitrogen narcosis may become too confused to swim back into shallower waters, and some never make it back to the surface. Water clarity and light both decrease significantly with depth, adding to the disorientation divers experience. Divers must also remain aware of the animals they may encounter in these holes. Shark species including Bull sharks, reef sharks, and Hammerhead sharks have been seen making use of Blue holes, and occasionally attack humans. In recent years, Dean's Blue Hole and the Great Blue Hole have claimed over 200 lives each, many of which occurred due to divers pushing past the limits of their training.

See also

References

  1. Mylroie, J. E., Carew, J. L., and Moore, A. I., (1995), Blue Holes: Definition and Genesis: Carbonates and Evaporites, v. 10, no. 2, p. 225.
  2. Sajady, Mas (2014). The Real Why. Balboa Prints. ISBN 9781452595993. 
  3. Stephanie Pappas (July 27, 2016). "World's Deepest Blue Hole Is in South China Sea". LiveScience. http://www.livescience.com/55568-deepest-blue-hole-in-south-china-sea.html. 
  4. 4.0 4.1 Francesca Street (October 8, 2019). "Dispatches from the bottom of Belize's Blue Hole". Cable News Network. https://www.cnn.com/travel/article/blue-hole-belize-expedition/index.html. 
  5. 5.0 5.1 Dave Mosher (February 3, 2012). "New Life-Forms Found in Blue Holes—Clues to Life in Alien Oceans?". National Geographic. https://www.nationalgeographic.com/news/2012/2/120202-blue-holes-new-life-alien-oceans-europa-space-science/. 
  6. Devotor (July 7, 2019). "8 Most Fascinating Blue Holes in the World". Charismatic Planet. https://charismaticplanet.com/blue-holes-in-the-world/. 
  7. Wyrwoll, Karl-Heinz; Zhu, Zhong Rong; Collins, Lindsay B.; Hatcher, Bruce G. (January 2006). "Origin of Blue Hole Structures in Coral Reefs: Houtman Abrolhos, Western Australia". Journal of Coastal Research 221: 202–208. doi:10.2112/05a-0015.1. ISSN 0749-0208. http://dx.doi.org/10.2112/05a-0015.1. 
  8. 8.0 8.1 8.2 8.3 8.4 Smith, Megan E.; Wynn, Jonathan G.; Scharping, Robert J.; Moore, Evan W.; Garey, James R.; Onac, Bogdan P. (2020-11-26). "Source of saline groundwater on tidally influenced blue holes on San Salvador Island, Bahamas". Hydrogeology Journal 29 (1): 429–441. doi:10.1007/s10040-020-02266-z. ISSN 1431-2174. http://dx.doi.org/10.1007/s10040-020-02266-z. 
  9. Keen, Cathy (December 3, 2007). "Fossils excavated from Bahamian blue hole may give clues of early life.". University of Florida. http://news.ufl.edu/2007/12/03/bahamian-fossils/. 
  10. 10.0 10.1 He, Peiqing; Xie, Linping; Zhang, Xuelei; Li, Jiang; Lin, Xuezheng; Pu, Xinming; Yuan, Chao; Tian, Ziwen et al. (2020-04-06). "Microbial Diversity and Metabolic Potential in the Stratified Sansha Yongle Blue Hole in the South China Sea". Scientific Reports 10 (1): 5949. doi:10.1038/s41598-020-62411-2. ISSN 2045-2322. PMID 32249806. Bibcode2020NatSR..10.5949H. 
  11. 11.0 11.1 van Hengstum, Peter; Winkler, Tyler; Tamalavage, Anne; Sullivan, Richard; Little, Shawna; MacDonald, Dana; Donelly, Jeffery; Allbury, Nancy (2020). "Holocene sedimentation in a blue hole surrounded by carbonate tidal flats in The Bahamas: Autogenic versus allogenic processes". Marine Geology 419: 106051. doi:10.1016/j.margeo.2019.106051. Bibcode2020MGeol.419j6051V. 
  12. Gonzalez, Brett C.; Iliffe, Thomas M.; Macalady, Jennifer L.; Schaperdoth, Irene; Kakuk, Brian (November 2011). "Microbial hotspots in anchialine blue holes: initial discoveries from the Bahamas" (in en). Hydrobiologia 677 (1): 149–156. doi:10.1007/s10750-011-0932-9. ISSN 0018-8158. http://link.springer.com/10.1007/s10750-011-0932-9. 
  13. 13.0 13.1 Todhunter, Andrew (August 2010). "Deep Dark Secrets". https://www.nationalgeographic.com/magazine/2010/08/bahamas-caves-underwater-blue-holes/. 
  14. Dockrill, Peter (July 21, 2020). "Researchers Embark to Explore Mysterious 'Blue Hole' Hidden Off The Coast of Florida". https://www.sciencealert.com/scientists-embark-to-explore-mysterious-blue-hole-hidden-off-the-coast-of-florida. 
  15. "Scientists Embark on Journey to the "Deep" to Explore Blue Holes". Ocean Research and Exploration. https://oceanexplorer.noaa.gov/explorations/20blue-holes/welcome.html. 
  16. Delbert, Caroline (July 22, 2020). "Why Divers Are Venturing Deep Inside a Baffling Blue Hole". Popular Mechanics. https://www.popularmechanics.com/science/a33382170/green-banana-blue-hole-sink-hole/. 
  17. Allison Meier (January 8, 2014). "Blue Holes: A Descent into the World's Hidden Waters". Atlas Obscura. https://www.atlasobscura.com/articles/guide-to-blue-holes. 

Further reading

External links




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