Hadal zone explained

The hadal zone, also known as the hadopelagic zone, is the deepest region of the ocean, lying within oceanic trenches. The hadal zone ranges from around below sea level, and exists in long, narrow, topographic V-shaped depressions.[1] [2]

The cumulative area occupied by the 46 individual hadal habitats worldwide is less than 0.25% of the world's seafloor, yet trenches account for over 40% of the ocean's depth range.[3] Most hadal habitat is found in the Pacific Ocean, the deepest of the conventional oceanic divisions.[3]

Terminology and definition

Historically, the hadal zone was not recognized as distinct from the abyssal zone, although the deepest sections were sometimes called "ultra-abyssal". During the early 1950s, the Danish Galathea II and Soviet Vityaz expeditions separately discovered a distinct shift in the life at depths of NaNm (-2,147,483,648feet) not recognized by the broad definition of the abyssal zone.[4] [5] The term "hadal" was first proposed in 1956 by Anton Frederik Bruun to describe the parts of the ocean deeper than 6000m (20,000feet), leaving abyssal for the parts at NaNm (-2,147,483,648feet).[6] The name refers to Hades, the ancient Greek god of the underworld.[6] About 94% of the hadal zone is found in subduction trenches.[7]

Depths in excess of 6000m (20,000feet) are generally in ocean trenches, but there are also trenches at shallower depths. These shallower trenches lack the distinct shift in lifeforms and are therefore not hadal.[8] [9] [10] Although the hadal zone has gained widespread recognition and many continue to use the first proposed limit of 6000m (20,000feet), it has been observed that NaNm (-2,147,483,648feet) represents a gradual transition between the abyssal and hadal zones, leading to the suggestion of placing the limit in the middle, at 6500m (21,300feet). Among others, this intermediate limit has been adopted by UNESCO.[11] [12] Similar to other depth ranges, the fauna of the hadal zone can be broadly placed into two groups: the hadobenthic species (compare benthic) living on or at the seabottom/sides of trenches, and the hadopelagic species (compare pelagic) living in the open water.[13] [14]

Ecology

The deepest ocean trenches are considered the least explored and most extreme marine ecosystems. They are characterized by complete lack of sunlight, low temperatures, nutrient scarcity, and extremely high hydrostatic pressures. The major sources of nutrients and carbon are fallout from upper layers, drifts of fine sediment, and landslides. Most organisms are scavengers and detrivores. Over 400 species are currently known from hadal ecosystems, many of which possess physiological adaptations to the extreme environmental conditions. There are high levels of endemism, and noteworthy examples of gigantism in amphipods, mysids, and isopods and dwarfism in nematodes, copepods, and kinorhynchs.[15]

Marine life decreases with depth, both in abundance and biomass, but there is a wide range of metazoan organisms in the hadal zone, mostly benthos, including fish, sea cucumber, bristle worms, bivalves, isopods, sea anemones, amphipods, copepods, decapod crustaceans and gastropods. Most of these trench communities probably originated from the abyssal plains. Although they have evolved adaptations to high pressure and low temperatures such as lower metabolism, intra-cellular protein-stabilising osmolytes, and unsaturated fatty acids in cell membrane phospholipids, there is no consistent relationship between pressure and metabolic rate in these communities. Increased pressure can instead constrain the ontogenic or larval stages of organisms. Pressure increases ten-fold as an organism moves from sea level to a depth of 90m (300feet), whilst pressure only doubles as an organism moves from 6000mto11000mm (20,000feetto36,000feetm).

Over a geological time scale, trenches can become accessible as previously stenobathic (limited to a narrow depth range) fauna evolve to become eurybathic (adapted to a wider range of depths), such as grenadiers and natantian prawns. Trench communities do, nevertheless, display a contrasting degree of intra-trench endemism and inter-trench similarities at a higher taxonomic level.

Only a relatively small number of fish species are known from the hadal zone, including certain grenadiers, cutthroat eels, pearlfish, cusk-eels, snailfish and eelpouts.[16] [17] Due to the extreme pressure, the theoretical maximum depth for vertebral fish may be about NaNm (-2,147,483,648feet), below which teleosts would be hyperosmotic, assuming trimethylamine N-oxide requirements follow the observed approximate linear relationship with depth.[18] [19] Some invertebrates do occur deeper, such as bigfin squid,[20] [21] certain polynoid worms, myriotrochid sea cucumbers, turrid snails and pardaliscid amphipods in excess of 10000m (30,000feet).[9] In addition, giant protists known as Xenophyophora (foraminifera) live at these depths.[22]

Conditions

The only known primary producers in the hadal zone are certain bacteria that are able to metabolize hydrogen and methane released by rock and seawater reactions (serpentinization),[23] or hydrogen sulfide released from cold seeps. Some of these bacteria are symbiotic, for example living inside the mantle of certain thyasirid and vesicomyid bivalves.[24] Otherwise the first link in the hadal food web are heterotroph organisms that feed on marine snow, both fine particles and the occasional carcass.[23] [25]

The hadal zone can reach far below 6000m (20,000feet) deep; the deepest known extends to 10911m (35,797feet).[26] At such depths, the pressure in the hadal zone exceeds 1100atm. Lack of light and extreme pressure makes this part of the ocean difficult to explore.

Exploration

The exploration of the hadal zone requires the use of instruments that are able to withstand pressures of up to a thousand or more atmospheres. A few haphazard and non-standard tools have been used to collect limited, but valuable, information about the basic biology of a few hadal organisms. Manned and unmanned submersibles, however, can be used to study the depths in greater detail. Unmanned robotic submersibles may be remotely operated (connected to the research vessel by a cable) or autonomous (freely moving). Cameras and manipulators on submersibles allow researchers to observe and take samples of sediment and organisms. Failures of submersibles under the immense pressure at hadal zone depths have occurred. HROV Nereus is thought to have imploded at a depth of 9,990 meters while exploring the Kermadec Trench in 2014.

Notable missions

The first manned exploration to reach Challenger Deep, the deepest known part of the ocean located in the Mariana Trench, was accomplished in 1960 by Jacques Piccard and Don Walsh.[27] They reached a maximum depth of 10911m (35,797feet) in the bathyscaphe Trieste.[28] [29]

James Cameron also reached the bottom of Mariana Trench in March 2012 using the Deepsea Challenger.[30] The descent of the Deepsea Challenger reached a depth of 10908m (35,787feet), slightly less than the deepest dive record set by Piccard and Walsh.[31] Cameron holds the record for the deepest solo dive.

In June 2012, the Chinese manned submersible Jiaolong was able to reach 7020m (23,030feet) deep in the Mariana Trench, making it the deepest diving manned research submersible.[32] [33] This range surpasses that of the previous record holder, the Japanese-made Shinkai, whose maximum depth is 6500m (21,300feet).[34]

Few unmanned submersibles are capable of descending to maximum hadal depths. The deepest diving unmanned submersibles have included the Kaikō (lost at sea in 2003),[35] the ABISMO,[36] the Nereus (lost at sea in 2014),[37] and the Haidou-1.[38]

See also

External links

Notes and References

  1. Jamieson. Alan J.. Alan Jamieson. Malkocs. Tamas. Piertney. Stuart B.. Fujii. Toyonobu. Zhang. Zulin. 13 February 2017. Bioaccumulation of persistent organic pollutants in the deepest ocean fauna. live. Nature Ecology & Evolution. 1. 3. 0051. 10.1038/s41559-016-0051. https://web.archive.org/web/20171011052313/https://www.cbd.int/financial/2017docs/pop-fauna.pdf. 11 October 2017. 28812719. 2017NatEE...1...51J . 2164/9142. 9192602. free.
  2. Web site: Hadal zone: Ten things you never knew about the ocean's deepest places. Jamieson. Alan. Alan Jamieson. 5 March 2016. International Business Times. live. https://web.archive.org/web/20190602221949/https://www.ibtimes.co.uk/hadal-zone-ten-things-you-never-knew-about-oceans-deepest-places-1547518. 2 June 2019.
  3. Web site: All About Trenches. Jamieson. Alan. Alan Jamieson. 29 April 2014. Hadal Ecosystem Studies. Woods Hole Oceanographic Institution. live. https://web.archive.org/web/20190820163503/https://web.whoi.edu/hades/all-about-trenches/. 20 August 2019.
  4. Wolff. Torben. 1959. The hadal community, an introduction. Deep Sea Research. 6. 95–124. 1959DSR.....6...95W. 10.1016/0146-6313(59)90063-2.
  5. Jamieson. Alan J.. Alan Jamieson. Fujii. Toyonobu. Mayor. Daniel J.. Solan. Martin. Priede. Imants G.. 2010. Hadal trenches: the ecology of the deepest places on Earth (Review article). dead. Trends in Ecology and Evolution. 25. 3. 190–197. 10.1016/j.tree.2009.09.009. https://web.archive.org/web/20171225035341/http://izt.ciens.ucv.ve/ecologia/Archivos/ECO_POB%202010/ECOPO7_2010/Jamieson%20et%20al%202010.pdf. 25 December 2017. 9 April 2017. 19846236.
  6. Bruun. Anton Frederik. Anton Frederik Bruun. 16 June 1956. The Abyssal Fauna: Its Ecology, Distribution and Origin. Nature. 177. 4520. 1105–1108. 1956Natur.177.1105B. 10.1038/1771105a0. 4182886.
  7. https://academic.oup.com/icesjms/article/79/4/1048/6576454?login=false Exponential growth of hadal science: perspectives and future directions identified using topic modelling
  8. Book: The First Global Integrated Marine Assessment, World Oceans Assessment I. United Nations. Cambridge University Press. 2017. 978-1-316-51001-8. 904. 2017287717.
  9. Book: The Hadal Zone: Life in the Deepest Oceans. Jamieson. Alan Jamieson. Cambridge University Press. 2015. 978-1-107-01674-3. 18–21, 285–318. 2014006998.
  10. Book: eLS. Jamieson. Alan Jamieson. John Wiley & Sons, Ltd. 2011. 978-0470016176. Ecology of Deep Oceans: Hadal Trenches. 10.1002/9780470015902.a0023606.
  11. Book: Marine Conservation Ecology. Roff. John. Zacharias. Mark. Earthscan. 2011. 978-1-84407-884-4.
  12. Book: Global Open Oceans and Deep Seabed (GOODS) – Biogeographic Classification. UNESCO. 2009. Vierros. Marjo. IOC Technical Series. Paris. 23 December 2017. Cresswell. Ian. Escobar Briones. Elva. Rice. Jake. Ardron. Jeff.
  13. Book: The Living Ocean: Understanding and Protecting Marine Biodiversity. Thorne-Miller. Boyce. Catena. John. John Wiley & Sons. 1999. 1-55963-678-5. Second. 57.
  14. Book: An Introduction to Marine Science. Meadows. P.S.. Campbell. J.I.. Wiley. 1988. 978-0-470-20951-6. 2nd. Tertiary Level Biology. 7. 87020603.
  15. Book: Ramirez-Llodra . E . Rowden . AA . Jamieson . AJ . Alan Jamieson. Priede . IG . Keith . DA . 2020 . M3.6 Hadal trenches and troughs . https://global-ecosystems.org/explore/groups/M3.6 . Keith . D.A. . Ferrer-Paris . J.R. . Nicholson . E. . Kingsford . R.T. . The IUCN Global Ecosystem Typology 2.0: Descriptive profiles for biomes and ecosystem functional groups . Gland, Switzerland . IUCN . 10.2305/IUCN.CH.2020.13.en . 978-2-8317-2077-7. 241360441 .
  16. Linley. Thomas D.. Gerringer. Mackenzie E.. Yancey. Paul H.. Drazen. Jeffrey C.. Weinstock. Chloe L.. Jamieson. Alan J.. Alan Jamieson. August 2016. Fishes of the hadal zone including new species, in situ observations and depth records of Liparidae. . 114. 99–110. 2016DSRI..114...99L. 10.1016/j.dsr.2016.05.003. free.
  17. Jamieson . Alan J. . Linley . Thomas D. . Eigler . Shane . Macdonald . Tim . A global assessment of fishes at lower abyssal and upper hadal depths (5000 to 8000 m). Deep Sea Research Part I: Oceanographic Research Papers . 1 December 2021 . 178 . 103642 . 10.1016/j.dsr.2021.103642 . 2021DSRI..17803642J . 239087034 . en . 0967-0637.
  18. Jamieson. Alan J.. Alan Jamieson. Yancey. Paul H.. June 2012. On the Validity of the Trieste Flatfish: Dispelling the Myth. live. The Biological Bulletin. 222. 3. 171–175. 10.1086/BBLv222n3p171. 41638633. 22815365. 31549749. https://web.archive.org/web/20191209070916/https://www.journals.uchicago.edu/doi/pdfplus/10.1086/BBLv222n3p171. 2019-12-09.
  19. Yanceya. Paul H.. Gerringera. Mackenzie E.. Drazen. Jeffrey C.. Rowden. Ashley A.. Jamieson. Alan. Alan Jamieson. March 2014. Marine fish may be biochemically constrained from inhabiting the deepest ocean depths. live. PNAS. 111. 12. 4461–4465. 2014PNAS..111.4461Y. 10.1073/pnas.1322003111. 3970477. 24591588. https://web.archive.org/web/20190704145853/https://www.pnas.org/content/pnas/111/12/4461.full.pdf. 2019-07-04. free.
  20. Jamieson . Alan J. . Vecchione . Michael . 2021-12-02 . Hadal cephalopods: first squid observation (Oegopsida, Magnapinnidae, Magnapinna sp.) and new records of finned octopods (Cirrata) at depths > 6000 m in the Philippine Trench . Marine Biology . en . 169 . 1 . 11 . 10.1007/s00227-021-03993-x . 1432-1793.
  21. Web site: Brandon Specktor . 2022-01-18 . World's deepest-dwelling squid spotted 20,000 feet under the sea . 2024-06-30 . livescience.com . en.
  22. https://news.mongabay.com/2011/10/giant-one-celled-organisms-discovered-over-six-miles-below-the-oceans-surface/ Giant one-celled organisms discovered over six miles below the ocean’s surface
  23. Web site: What Lives at the Bottom of the Mariana Trench? More Than You Might Think. Frazer. Jennifer. 14 April 2013. Scientific American. dead. https://web.archive.org/web/20190205034240/https://blogs.scientificamerican.com/artful-amoeba/what-lives-at-the-bottom-of-the-mariana-trench-more-than-you-might-think/. 5 February 2019.
  24. Fujikura. Katsunori. Kojima. Shigeaki. Tamaki. Kensaku. Maki. Yonosuke. Hunt. James. Okutani. Takashi. 4 December 1999. The deepest chemosynthesis-based community yet discovered from the hadal zone, 7326 m deep, in the Japan Trench. live. Marine Ecology Progress Series. 190. 17–26. 1999MEPS..190...17F. 10.3354/meps190017. 24854626. https://web.archive.org/web/20190502063045/https://www.int-res.com/articles/meps/190/m190p017.pdf. 2 May 2019. free.
  25. Blankenship. Lesley E.. Levin. Lisa A.. Lisa Levin. July 2007. Extreme food webs: Foraging strategies and diets of scavenging amphipods from the ocean's deepest 5 kilometers. Limnology and Oceanography. 52. 4. 1685–1697. 2007LimOc..52.1685B. 10.4319/lo.2007.52.4.1685. 4502323. free.
  26. Web site: NOAA Ocean Explorer: History: Quotations: Soundings, Sea-Bottom, and Geophysics. NOAA, Office of Ocean Exploration and Research. 2010-03-23.
  27. http://library.thinkquest.org/04oct/00116/hadal.htm ThinkQuest
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  29. Web site: About Hades. Hadal Ecosystem Studies. Woods Hole Oceanographic Institution. live. https://web.archive.org/web/20190820163547/https://web.whoi.edu/hades/about-hades/. 2019-08-20. 2018-04-06.
  30. Web site: James Cameron Completes Record-Breaking Mariana Trench Dive. Than. Ker. March 25, 2012. National Geographic. dead. https://web.archive.org/web/20190919151244/https://www.nationalgeographic.com/news/2012/3/120325-james-cameron-mariana-trench-challenger-deepest-returns-science-sub/. September 19, 2019.
  31. Web site: 2014-06-25 . DEEPSEA CHALLENGE – National Geographic Explorer James Cameron's Expedition . 2022-01-01 . https://web.archive.org/web/20140625050833/http://deepseachallenge.com/ . 25 June 2014 . dead.
  32. News: Jiaolong Reaches 7.000 Meters Below Water. Subsea World News. 2018-04-06. en-US.
  33. Web site: China's Jiaolong submersible plunges below 7,000 metres. Owens. Brian. 25 Jun 2012. blogs.nature.com. en-US. live. https://web.archive.org/web/20191112164107/http://blogs.nature.com/news/2012/06/chinas-jiaolong-submersible-plunges-below-7000-metres.html. 2019-11-12. 2018-04-06.
  34. Web site: Deep Submergence Research Vehicle – Shinkai 6500. JAMSTEC. live. https://web.archive.org/web/20190518211231/https://www.jamstec.go.jp/e/about/equipment/ships/shinkai6500.html. 2019-05-18. 2018-04-06.
  35. Web site: Remotely Operated Vehicle – Kaiko. JAMSTEC. live. https://web.archive.org/web/20190902190540/https://www.jamstec.go.jp/e/about/equipment/ships/kaiko.html. 2019-09-02. 2018-04-06.
  36. "ABISMO," Automatic Bottom Inspection and Sampling Mobile, Succeeds in World's First Multiple Vertical Sampling from Mid-ocean, Sea Floor and Sub-seafloor over Depth of 10,000 m in Mariana Trench. 2018-04-06. 2008-06-16. JAMSTEC. 2018-11-16. https://web.archive.org/web/20181116171807/https://www.jamstec.go.jp/e/about/press_release/20080616/. live.
  37. Robotic Deep-sea Vehicle Lost on Dive to 6-Mile Depth. 2014-05-10. Woods Hole Oceanographic Institution. live. https://web.archive.org/web/20191209064433/https://www.whoi.edu/press-room/news-release/Nereus-Lost/. 2019-12-09. 2018-04-06.
  38. News: China's Unmanned Submersible Sets New National Record. 2016-08-23. 2019-12-09. live. https://archive.today/20191209065151/https://www.ndtv.com/world-news/chinas-unmanned-submersible-sets-new-national-record-1449082. 2019-12-09. NDTV. Press Trust of India.