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Deep-sea community

December 02, 2023

A deep-sea community is any community of organisms associated by a shared habitat in the deep sea. Deep sea communities remain largely unexplored, due to the technological and logistical challenges and expense involved in visiting this remote biome. Because of the unique challenges (particularly the high barometric pressure, extremes of temperature and absence of light), it was long believed that little life existed in this hostile environment. Since the 19th century however, research has demonstrated that significant biodiversity exists in the deep sea.

Giant tube worms
Asterechinus elegans

The three main sources of energy and nutrients for deep sea communities are marine snow, whale falls, and chemosynthesis at hydrothermal vents and cold seeps.

History edit

Prior to the 19th century scientists assumed life was sparse in the deep ocean. In the 1870s Sir Charles Wyville Thomson and colleagues aboard the Challenger expedition discovered many deep-sea creatures of widely varying types.

The first discovery of any deep-sea chemosynthetic community including higher animals was unexpectedly made at hydrothermal vents in the eastern Pacific Ocean during geological explorations (Corliss et al., 1979).[1] Two scientists, J. Corliss and J. van Andel, first witnessed dense chemosynthetic clam beds from the submersible DSV Alvin on February 17, 1977, after their unanticipated discovery using a remote camera sled two days before.[1]

The Challenger Deep is the deepest surveyed point of all of Earth's oceans; it is located at the southern end of the Mariana Trench near the Mariana Islands group. The depression is named after HMS Challenger, whose researchers made the first recordings of its depth on 23 March 1875 at . The reported depth was 4,475 fathoms (8184 meters) based on two separate soundings. In 1960, Don Walsh and Jacques Piccard descended to the bottom of the Challenger Deep in the Trieste bathyscaphe. At this great depth a small flounder-like fish was seen moving away from the spotlight of the bathyscaphe.

The Japanese remote operated vehicle (ROV) Kaiko became the second vessel to reach the bottom of the Challenger Deep in March 1995. Nereus, a hybrid remotely operated vehicle (HROV) of the Woods Hole Oceanographic Institution, is the only vehicle capable of exploring ocean depths beyond 7000 meters. Nereus reached a depth of 10,902 meters at the Challenger Deep on May 31, 2009.[2][3] On 1 June 2009, sonar mapping of the Challenger Deep by the Simrad EM120 multibeam sonar bathymetry system aboard the R/V Kilo Moana indicated a maximum depth of 10,971 meters (6.817 miles). The sonar system uses phase and amplitude bottom detection, with an accuracy of better than 0.2% of water depth (this is an error of about 22 meters at this depth).[3][4]

Environment edit

Darkness edit

 
Pelagic zones

The ocean can be conceptualized as being divided into various zones, depending on depth, and presence or absence of sunlight. Nearly all life forms in the ocean depend on the photosynthetic activities of phytoplankton and other marine plants to convert carbon dioxide into organic carbon, which is the basic building block of organic matter. Photosynthesis in turn requires energy from sunlight to drive the chemical reactions that produce organic carbon.[5]

The stratum of the water column up till which sunlight penetrates is referred to as the photic zone. The photic zone can be subdivided into two different vertical regions. The uppermost portion of the photic zone, where there is adequate light to support photosynthesis by phytoplankton and plants, is referred to as the euphotic zone (also referred to as the epipelagic zone, or surface zone).[6] The lower portion of the photic zone, where the light intensity is insufficient for photosynthesis, is called the dysphotic zone (dysphotic means "poorly lit" in Greek).[7] The dysphotic zone is also referred to as the mesopelagic zone, or the twilight zone.[8] Its lowermost boundary is at a thermocline of 12 °C (54 °F), which, in the tropics generally lies between 200 and 1000 meters.[9]

The euphotic zone is somewhat arbitrarily defined as extending from the surface to the depth where the light intensity is approximately 0.1–1% of surface sunlight irradiance, depending on season, latitude and degree of water turbidity.[6][7] In the clearest ocean water, the euphotic zone may extend to a depth of about 150 meters,[6] or rarely, up to 200 meters.[8] Dissolved substances and solid particles absorb and scatter light, and in coastal regions the high concentration of these substances causes light to be attenuated rapidly with depth. In such areas the euphotic zone may be only a few tens of meters deep or less.[6][8] The dysphotic zone, where light intensity is considerably less than 1% of surface irradiance, extends from the base of the euphotic zone to about 1000 meters.[9] Extending from the bottom of the photic zone down to the seabed is the aphotic zone, a region of perpetual darkness.[8][9]

Since the average depth of the ocean is about 3688 meters,[10] the photic zone represents only a tiny fraction of the ocean's total volume. However, due to its capacity for photosynthesis, the photic zone has the greatest biodiversity and biomass of all oceanic zones. Nearly all primary production in the ocean occurs here. Any life forms present in the aphotic zone must either be capable of movement upwards through the water column into the photic zone for feeding, or must rely on material sinking from above,[5] or must find another source of energy and nutrition, such as occurs in chemosynthetic archaea found near hydrothermal vents and cold seeps.

Hyperbaricity edit

Further information: Barophile
 
Location of the Challenger Deep in the Mariana Trench

These animals have evolved to survive the extreme pressure of the sub-photic zones. The pressure increases by about one atmosphere every ten meters. To cope with the pressure, many fish are rather small, usually not exceeding 25 cm in length. Also, scientists have discovered that the deeper these creatures live, the more gelatinous their flesh and more minimal their skeletal structure. These creatures have also eliminated all excess cavities that would collapse under the pressure, such as swim bladders.[11]

Pressure is the greatest environmental factor acting on deep-sea organisms. In the deep sea, although most of the deep sea is under pressures between 200 and 600 atm, the range of pressure is from 20 to 1,000 atm. Pressure exhibits a great role in the distribution of deep sea organisms. Until recently, people lacked detailed information on the direct effects of pressure on most deep-sea organisms, because virtually all organisms trawled from the deep sea arrived at the surface dead or dying. With the advent of traps that incorporate a special pressure-maintaining chamber, undamaged larger metazoan animals have been retrieved from the deep sea in good condition. Some of these have been maintained for experimental purposes, and we are obtaining more knowledge of the biological effects of pressure.

Temperature edit

Further information: Thermophile

The two areas of greatest and most rapid temperature change in the oceans are the transition zone between the surface waters and the deep waters, the thermocline, and the transition between the deep-sea floor and the hot water flows at the hydrothermal vents. Thermoclines vary in thickness from a few hundred meters to nearly a thousand meters. Below the thermocline, the water mass of the deep ocean is cold and far more homogeneous. Thermoclines are strongest in the tropics, where the temperature of the epipelagic zone is usually above 20 °C. From the base of the epipelagic, the temperature drops over several hundred meters to 5 or 6 °C at 1,000 meters. It continues to decrease to the bottom, but the rate is much slower. Below 3,000 to 4,000 m, the water is isothermal. At any given depth, the temperature is practically unvarying over long periods of time. There are no seasonal temperature changes, nor are there any annual changes. No other habitat on earth has such a constant temperature.

Hydrothermal vents are the direct contrast with constant temperature. In these systems, the temperature of the water as it emerges from the "black smoker" chimneys may be as high as 400 °C (it is kept from boiling by the high hydrostatic pressure) while within a few meters it may be back down to 2–4 °C.[12]

Salinity edit

Further information: Halophile
 
NOAA rendering of a brine pool in the Gulf of Mexico

Salinity is constant throughout the depths of the deep sea. There are two notable exceptions to this rule:

  1. In the Mediterranean Sea, water loss through evaporation greatly exceeds input from precipitation and river runoff. Because of this, salinity in the Mediterranean is higher than in the Atlantic Ocean.[13] Evaporation is especially high in its eastern half, causing the water level to decrease and salinity to increase in this area.[14] The resulting pressure gradient pushes relatively cool, low-salinity water from the Atlantic Ocean across the basin. This water warms and becomes saltier as it travels eastward, then sinks in the region of the Levant and circulates westward, to spill back into the Atlantic over the Strait of Gibraltar.[15] The net effect of this is that at the Strait of Gibraltar, there is an eastward surface current of cold water of lower salinity from the Atlantic, and a simultaneous westward current of warm saline water from the Mediterranean in the deeper zones. Once back in the Atlantic, this chemically distinct Mediterranean Intermediate Water can persist for thousands of kilometers away from its source.[16]
  2. Brine pools are large areas of brine on the seabed. These pools are bodies of water that have a salinity that is three to five times greater than that of the surrounding ocean. For deep sea brine pools the source of the salt is the dissolution of large salt deposits through salt tectonics. The brine often contains high concentrations of methane, providing energy to chemosynthetic extremophiles that live in this specialized biome. Brine pools are also known to exist on the Antarctic continental shelf where the source of brine is salt excluded during formation of sea ice. Deep sea and Antarctic brine pools can be toxic to marine animals. Brine pools are sometimes called seafloor lakes because the dense brine creates a halocline which does not easily mix with overlying seawater. The high salinity raises the density of the brine, which creates a distinct surface and shoreline for the pool.[17]

The deep sea, or deep layer, is the lowest layer in the ocean, existing below the thermocline, at a depth of 1000 fathoms (1800 m) or more. The deepest part of the deep sea is Mariana Trench located in the western North Pacific. It is also the deepest point of the Earth's crust. It has a maximum depth of about 10.9 km which is deeper than the height of Mount Everest. In 1960, Don Walsh and Jacques Piccard reached the bottom of Mariana Trench in the Trieste bathyscaphe. The pressure is about 11,318 metric tons-force per square meter (110.99 MPa or 16100 psi).

Zones edit

Further information: Benthic zone, Benthos, Benthic fish, Benthopelagic fish, and Demersal fish

Mesopelagic edit

Main articles: Mesopelagic zone and Mesopelagic fish
 
Most mesopelagic fish are ambush predators with upward-facing eyes, like this sabertooth fish.

The mesopelagic zone is the upper section of the midwater zone, and extends from 200 to 1,000 metres (660 to 3,280 ft) below sea level. This is colloquially known as the "twilight zone" as light can still penetrate this layer, but it is too low to support photosynthesis. The limited amount of light, however, can still allow organisms to see, and creatures with a sensitive vision can detect prey, communicate, and orientate themselves using their sight. Organisms in this layer have large eyes to maximize the amount of light in the environment.[18]

Most mesopelagic fish make daily vertical migrations, moving at night into the epipelagic zone, often following similar migrations of zooplankton, and returning to the depths for safety during the day.[19][20]: 585  These vertical migrations often occur over a large vertical distances, and are undertaken with the assistance of a swimbladder. The swimbladder is inflated when the fish wants to move up, and, given the high pressures in the mesopelegic zone, this requires significant energy. As the fish ascends, the pressure in the swimbladder must adjust to prevent it from bursting. When the fish wants to return to the depths, the swimbladder is deflated.[21] Some mesopelagic fishes make daily migrations through the thermocline, where the temperature changes between 10 and 20 °C (18 and 36 °F), thus displaying considerable tolerances for temperature change.[20]: 590 

Mesopelagic fish usually lack defensive spines, and use colour and bioluminescence to camouflage them from other fish. Ambush predators are dark, black or red. Since the longer, red, wavelengths of light do not reach the deep sea, red effectively functions the same as black. Migratory forms use countershaded silvery colours. On their bellies, they often display photophores producing low grade light. For a predator from below, looking upwards, this bioluminescence camouflages the silhouette of the fish. However, some of these predators have yellow lenses that filter the (red deficient) ambient light, leaving the bioluminescence visible.[22]

Bathyal edit

Main articles: Bathyal zone and Bathypelagic fish
 
Gulper eels use their mouth like a net to catch prey, and have a bioluminescent tail to attract prey.

The bathyl zone is the lower section of the midwater zone, and encompasses the depths of 1,000 to 4,000 metres (3,300 to 13,100 ft).[23] Light does not reach this zone, giving it its nickname "the midnight zone"; due to the lack of light, it is less densely populated than the epipelagic zone, despite being much larger.[24] Fish find it hard to live in this zone, as there is crushing pressure, cold temperatures of 4 °C (39 °F), a low level of dissolved oxygen, and a lack of sufficient nutrients.[20]: 585  What little energy is available in the bathypelagic zone filters from above in the form of detritus, faecal material, and the occasional invertebrate or mesopelagic fish.[20]: 594  About 20% of the food that has its origins in the epipelagic zone falls down to the mesopelagic zone, but only about 5% filters down to the bathypelagic zone.[25] The fish that do live there may have reduced or completely lost their gills, kidneys, hearts, and swimbladders, have slimy instead of scaly skin, and have a weak skeletal and muscular build.[20]: 587  This lack of ossification is an adaptation to save energy when food is scarce.[26] Most of the animals that live in the bathyl zone are invertebrates such as sea sponges, cephalopods, and echinoderms. With the exception of very deep areas of the ocean, the bathyl zone usually reaches the benthic zone on the seafloor.[24]

Abyssal and hadal edit

Main articles: Abyssal plain, Abyssal zone, and Hadal zone
 
Giant tube worms chemosynthesize near hydrothermal vents

The abyssal zone remains in perpetual darkness at a depth of 4,000 to 6,000 metres (13,000 to 20,000 ft).[23] The only organisms that inhabit this zone are chemotrophs and predators that can withstand immense pressures, sometimes as high as 76 megapascals (750 atm; 11,000 psi). The hadal zone (named after Hades, the Greek god of the underworld) is a zone designated for the deepest trenches in the world, reaching depths of below 6,000 metres (20,000 ft). The deepest point in the hadal zone is the Marianas Trench, which descends to 10,911 metres (35,797 ft) and has a pressure of 110 megapascals (1,100 atm; 16,000 psi).[27][28][29]

Energy sources edit

 
Wood fall as an energy source.

Marine snow edit

The upper photic zone of the ocean is filled with particle organic matter (POM) and is quite productive, especially in the coastal areas and the upwelling areas. However, most POM is small and light. It may take hundreds, or even thousands of years for these particles to settle through the water column into the deep ocean. This time delay is long enough for the particles to be remineralized and taken up by organisms in the food webs.

Scientists at Woods Hole Oceanographic Institution conducted an experiment three decades ago in deep Sargasso Sea looking at the rate of sinking.[30] They found what became known as marine snow in which the POM are repackaged into much larger particles which sink at much greater speed, 'falling like snow'.

Because of the sparsity of food, the organisms living on and in the bottom are generally opportunistic. They have special adaptations for this extreme environment: rapid growth, effect larval dispersal mechanism and the ability to use a 'transient' food resource. One typical example is wood-boring bivalves, which bore into wood and other plant remains and are fed on the organic matter from the remains.

Whale falls edit

For the deep-sea ecosystem, the death of a whale is the most important event. A dead whale can bring hundreds of tons of organic matter to the bottom. Whale fall community progresses through three stages:[31]

  1. Mobile scavenger stage: Big and mobile deep-sea animals arrive at the site almost immediately after whales fall on the bottom. Amphipods, crabs, sleeper sharks and hagfish are all scavengers.
  2. Opportunistic stage: Organisms arrive which colonize the bones and surrounding sediments that have been contaminated with organic matter from the carcass and any other tissue left by the scavengers. One genus is Osedax,[32] a tube worm. The larva is born without sex. The surrounding environment determines the sex of the larva. When a larva settles on a whale bone, it turns into a female; when a larva settles on or in a female, it turns into a dwarf male. One female Osedax can carry more than 200 of these male individuals in its oviduct.
  3. Sulfophilic stage: Further decomposition of bones and seawater sulfate reduction happen at this stage. Bacteria create a sulphide-rich environment analogous to hydrothermal vents. Polynoids, bivalves, gastropods and other sulphur-loving creatures move in.

Chemosynthesis edit

Hydrothermal vents edit

 
hydrothermal vent

Hydrothermal vents were discovered in 1977 by scientists from Scripps Institution of Oceanography. So far, the discovered hydrothermal vents are all located at the boundaries of plates: East Pacific, California, Mid-Atlantic ridge, China and Japan.

New ocean basin material is being made in regions such as the Mid-Atlantic ridge as tectonic plates pull away from each other. The rate of spreading of plates is 1–5 cm/yr. Cold sea water circulates down through cracks between two plates and heats up as it passes through hot rock. Minerals and sulfides are dissolved into the water during the interaction with rock. Eventually, the hot solutions emanate from an active sub-seafloor rift, creating a hydrothermal vent.

Chemosynthesis of bacteria provide the energy and organic matter for the whole food web in vent ecosystems. These vents spew forth very large amounts of chemicals, which these bacteria can transform into energy. These bacteria can also grow free of a host and create mats of bacteria on the sea floor around hydrothermal vents, where they serve as food for other creatures. Bacteria are a key energy source in the food chain. This source of energy creates large populations in areas around hydrothermal vents, which provides scientists with an easy stop for research. Organisms can also use chemosynthesis to attract prey or to attract a mate.[33]Giant tube worms can grow to 2.4 m (7 ft 10 in) tall because of the richness of nutrients. Over 300 new species have been discovered at hydrothermal vents.[34]

Hydrothermal vents are entire ecosystems independent from sunlight, and may be the first evidence that the earth can support life without the sun.

Cold seeps edit

A cold seep (sometimes called a cold vent) is an area of the ocean floor where hydrogen sulfide, methane and other hydrocarbon-rich fluid seepage occurs, often in the form of a brine pool.

Ecology edit

Deep sea food webs are complex, and aspects of the system are poorly understood. Typically, predator-prey interactions within the deep are compiled by direct observation (likely from remotely operated underwater vehicles), analysis of stomach contents, and biochemical analysis. Stomach content analysis is the most common method used, but it is not reliable for some species.[35]

In deep sea pelagic ecosystems off of California, the trophic web is dominated by deep sea fishes, cephalopods, gelatinous zooplankton, and crustaceans. Between 1991 and 2016, 242 unique feeding relationships between 166 species of predators and prey demonstrated that gelatinous zooplankton have an ecological impact similar to that of large fishes and squid. Narcomedusae, siphonophores (of the family Physonectae), ctenophores, and cephalopods consumed the greatest diversity of prey, in decreasing order.[35] Cannibalism has been documented in squid of the genus Gonatus.[36]

Deep sea research edit

 
Alvin in 1978, a year after it first explored a hydrothermal vent.

Humans have explored less than 4% of the ocean floor, and dozens of new species of deep sea creatures are discovered with every dive. The submarine DSV Alvin—owned by the US Navy and operated by the Woods Hole Oceanographic Institution (WHOI) in Woods Hole, Massachusetts—exemplifies the type of craft used to explore deep water. This 16 ton submarine can withstand extreme pressure and is easily manoeuvrable despite its weight and size.

The extreme difference in pressure between the sea floor and the surface makes creatures' survival on the surface near impossible; this makes in-depth research difficult because most useful information can only be found while the creatures are alive. Recent developments have allowed scientists to look at these creatures more closely, and for a longer time. Marine biologist Jeffery Drazen has explored a solution: a pressurized fish trap. This captures a deep-water creature, and adjusts its internal pressure slowly to surface level as the creature is brought to the surface, in the hope that the creature can adjust.[37]

Another scientific team, from the Université Pierre-et-Marie-Curie, has developed a capture device known as the PERISCOP, which maintains water pressure as it surfaces, thus keeping the samples in a pressurized environment during the ascent. This permits close study on the surface without any pressure disturbances affecting the sample.[38]

See also edit

References edit

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Further reading edit

  • Kupriyanova, E.K.; Vinn, O.; Taylor, P.D.; Schopf, J.W.; Kudryavtsev, A.B.; Bailey-Brock, J. (2014). "Serpulids living deep: calcareous tubeworms beyond the abyss". Deep-Sea Research Part I. 90: 91–104. Bibcode:2014DSRI...90...91K. doi:10.1016/j.dsr.2014.04.006.

December 02, 2023
deep, community, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, january, 2. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Deep sea community news newspapers books scholar JSTOR January 2021 Learn how and when to remove this template message A deep sea community is any community of organisms associated by a shared habitat in the deep sea Deep sea communities remain largely unexplored due to the technological and logistical challenges and expense involved in visiting this remote biome Because of the unique challenges particularly the high barometric pressure extremes of temperature and absence of light it was long believed that little life existed in this hostile environment Since the 19th century however research has demonstrated that significant biodiversity exists in the deep sea Giant tube wormsAsterechinus elegansThe three main sources of energy and nutrients for deep sea communities are marine snow whale falls and chemosynthesis at hydrothermal vents and cold seeps Contents 1 History 2 Environment 2 1 Darkness 2 2 Hyperbaricity 2 3 Temperature 2 4 Salinity 3 Zones 3 1 Mesopelagic 3 2 Bathyal 3 3 Abyssal and hadal 4 Energy sources 4 1 Marine snow 4 2 Whale falls 4 3 Chemosynthesis 4 3 1 Hydrothermal vents 4 3 2 Cold seeps 5 Ecology 6 Deep sea research 7 See also 8 References 9 Further readingHistory editPrior to the 19th century scientists assumed life was sparse in the deep ocean In the 1870s Sir Charles Wyville Thomson and colleagues aboard the Challenger expedition discovered many deep sea creatures of widely varying types The first discovery of any deep sea chemosynthetic community including higher animals was unexpectedly made at hydrothermal vents in the eastern Pacific Ocean during geological explorations Corliss et al 1979 1 Two scientists J Corliss and J van Andel first witnessed dense chemosynthetic clam beds from the submersible DSV Alvin on February 17 1977 after their unanticipated discovery using a remote camera sled two days before 1 The Challenger Deep is the deepest surveyed point of all of Earth s oceans it is located at the southern end of the Mariana Trench near the Mariana Islands group The depression is named after HMS Challenger whose researchers made the first recordings of its depth on 23 March 1875 at station 225 The reported depth was 4 475 fathoms 8184 meters based on two separate soundings In 1960 Don Walsh and Jacques Piccard descended to the bottom of the Challenger Deep in the Trieste bathyscaphe At this great depth a small flounder like fish was seen moving away from the spotlight of the bathyscaphe The Japanese remote operated vehicle ROV Kaiko became the second vessel to reach the bottom of the Challenger Deep in March 1995 Nereus a hybrid remotely operated vehicle HROV of the Woods Hole Oceanographic Institution is the only vehicle capable of exploring ocean depths beyond 7000 meters Nereus reached a depth of 10 902 meters at the Challenger Deep on May 31 2009 2 3 On 1 June 2009 sonar mapping of the Challenger Deep by the Simrad EM120 multibeam sonar bathymetry system aboard the R V Kilo Moana indicated a maximum depth of 10 971 meters 6 817 miles The sonar system uses phase and amplitude bottom detection with an accuracy of better than 0 2 of water depth this is an error of about 22 meters at this depth 3 4 Environment editDarkness edit nbsp Pelagic zonesThe ocean can be conceptualized as being divided into various zones depending on depth and presence or absence of sunlight Nearly all life forms in the ocean depend on the photosynthetic activities of phytoplankton and other marine plants to convert carbon dioxide into organic carbon which is the basic building block of organic matter Photosynthesis in turn requires energy from sunlight to drive the chemical reactions that produce organic carbon 5 The stratum of the water column up till which sunlight penetrates is referred to as the photic zone The photic zone can be subdivided into two different vertical regions The uppermost portion of the photic zone where there is adequate light to support photosynthesis by phytoplankton and plants is referred to as the euphotic zone also referred to as the epipelagic zone or surface zone 6 The lower portion of the photic zone where the light intensity is insufficient for photosynthesis is called the dysphotic zone dysphotic means poorly lit in Greek 7 The dysphotic zone is also referred to as the mesopelagic zone or the twilight zone 8 Its lowermost boundary is at a thermocline of 12 C 54 F which in the tropics generally lies between 200 and 1000 meters 9 The euphotic zone is somewhat arbitrarily defined as extending from the surface to the depth where the light intensity is approximately 0 1 1 of surface sunlight irradiance depending on season latitude and degree of water turbidity 6 7 In the clearest ocean water the euphotic zone may extend to a depth of about 150 meters 6 or rarely up to 200 meters 8 Dissolved substances and solid particles absorb and scatter light and in coastal regions the high concentration of these substances causes light to be attenuated rapidly with depth In such areas the euphotic zone may be only a few tens of meters deep or less 6 8 The dysphotic zone where light intensity is considerably less than 1 of surface irradiance extends from the base of the euphotic zone to about 1000 meters 9 Extending from the bottom of the photic zone down to the seabed is the aphotic zone a region of perpetual darkness 8 9 Since the average depth of the ocean is about 3688 meters 10 the photic zone represents only a tiny fraction of the ocean s total volume However due to its capacity for photosynthesis the photic zone has the greatest biodiversity and biomass of all oceanic zones Nearly all primary production in the ocean occurs here Any life forms present in the aphotic zone must either be capable of movement upwards through the water column into the photic zone for feeding or must rely on material sinking from above 5 or must find another source of energy and nutrition such as occurs in chemosynthetic archaea found near hydrothermal vents and cold seeps Hyperbaricity edit Further information Barophile nbsp Location of the Challenger Deep in the Mariana TrenchThese animals have evolved to survive the extreme pressure of the sub photic zones The pressure increases by about one atmosphere every ten meters To cope with the pressure many fish are rather small usually not exceeding 25 cm in length Also scientists have discovered that the deeper these creatures live the more gelatinous their flesh and more minimal their skeletal structure These creatures have also eliminated all excess cavities that would collapse under the pressure such as swim bladders 11 Pressure is the greatest environmental factor acting on deep sea organisms In the deep sea although most of the deep sea is under pressures between 200 and 600 atm the range of pressure is from 20 to 1 000 atm Pressure exhibits a great role in the distribution of deep sea organisms Until recently people lacked detailed information on the direct effects of pressure on most deep sea organisms because virtually all organisms trawled from the deep sea arrived at the surface dead or dying With the advent of traps that incorporate a special pressure maintaining chamber undamaged larger metazoan animals have been retrieved from the deep sea in good condition Some of these have been maintained for experimental purposes and we are obtaining more knowledge of the biological effects of pressure Temperature edit Further information Thermophile The two areas of greatest and most rapid temperature change in the oceans are the transition zone between the surface waters and the deep waters the thermocline and the transition between the deep sea floor and the hot water flows at the hydrothermal vents Thermoclines vary in thickness from a few hundred meters to nearly a thousand meters Below the thermocline the water mass of the deep ocean is cold and far more homogeneous Thermoclines are strongest in the tropics where the temperature of the epipelagic zone is usually above 20 C From the base of the epipelagic the temperature drops over several hundred meters to 5 or 6 C at 1 000 meters It continues to decrease to the bottom but the rate is much slower Below 3 000 to 4 000 m the water is isothermal At any given depth the temperature is practically unvarying over long periods of time There are no seasonal temperature changes nor are there any annual changes No other habitat on earth has such a constant temperature Hydrothermal vents are the direct contrast with constant temperature In these systems the temperature of the water as it emerges from the black smoker chimneys may be as high as 400 C it is kept from boiling by the high hydrostatic pressure while within a few meters it may be back down to 2 4 C 12 Salinity edit Further information Halophile nbsp NOAA rendering of a brine pool in the Gulf of MexicoSalinity is constant throughout the depths of the deep sea There are two notable exceptions to this rule In the Mediterranean Sea water loss through evaporation greatly exceeds input from precipitation and river runoff Because of this salinity in the Mediterranean is higher than in the Atlantic Ocean 13 Evaporation is especially high in its eastern half causing the water level to decrease and salinity to increase in this area 14 The resulting pressure gradient pushes relatively cool low salinity water from the Atlantic Ocean across the basin This water warms and becomes saltier as it travels eastward then sinks in the region of the Levant and circulates westward to spill back into the Atlantic over the Strait of Gibraltar 15 The net effect of this is that at the Strait of Gibraltar there is an eastward surface current of cold water of lower salinity from the Atlantic and a simultaneous westward current of warm saline water from the Mediterranean in the deeper zones Once back in the Atlantic this chemically distinct Mediterranean Intermediate Water can persist for thousands of kilometers away from its source 16 Brine pools are large areas of brine on the seabed These pools are bodies of water that have a salinity that is three to five times greater than that of the surrounding ocean For deep sea brine pools the source of the salt is the dissolution of large salt deposits through salt tectonics The brine often contains high concentrations of methane providing energy to chemosynthetic extremophiles that live in this specialized biome Brine pools are also known to exist on the Antarctic continental shelf where the source of brine is salt excluded during formation of sea ice Deep sea and Antarctic brine pools can be toxic to marine animals Brine pools are sometimes called seafloor lakes because the dense brine creates a halocline which does not easily mix with overlying seawater The high salinity raises the density of the brine which creates a distinct surface and shoreline for the pool 17 The deep sea or deep layer is the lowest layer in the ocean existing below the thermocline at a depth of 1000 fathoms 1800 m or more The deepest part of the deep sea is Mariana Trench located in the western North Pacific It is also the deepest point of the Earth s crust It has a maximum depth of about 10 9 km which is deeper than the height of Mount Everest In 1960 Don Walsh and Jacques Piccard reached the bottom of Mariana Trench in the Trieste bathyscaphe The pressure is about 11 318 metric tons force per square meter 110 99 MPa or 16100 psi Zones editFurther information Benthic zone Benthos Benthic fish Benthopelagic fish and Demersal fish Mesopelagic edit Main articles Mesopelagic zone and Mesopelagic fish nbsp Most mesopelagic fish are ambush predators with upward facing eyes like this sabertooth fish The mesopelagic zone is the upper section of the midwater zone and extends from 200 to 1 000 metres 660 to 3 280 ft below sea level This is colloquially known as the twilight zone as light can still penetrate this layer but it is too low to support photosynthesis The limited amount of light however can still allow organisms to see and creatures with a sensitive vision can detect prey communicate and orientate themselves using their sight Organisms in this layer have large eyes to maximize the amount of light in the environment 18 Most mesopelagic fish make daily vertical migrations moving at night into the epipelagic zone often following similar migrations of zooplankton and returning to the depths for safety during the day 19 20 585 These vertical migrations often occur over a large vertical distances and are undertaken with the assistance of a swimbladder The swimbladder is inflated when the fish wants to move up and given the high pressures in the mesopelegic zone this requires significant energy As the fish ascends the pressure in the swimbladder must adjust to prevent it from bursting When the fish wants to return to the depths the swimbladder is deflated 21 Some mesopelagic fishes make daily migrations through the thermocline where the temperature changes between 10 and 20 C 18 and 36 F thus displaying considerable tolerances for temperature change 20 590 Mesopelagic fish usually lack defensive spines and use colour and bioluminescence to camouflage them from other fish Ambush predators are dark black or red Since the longer red wavelengths of light do not reach the deep sea red effectively functions the same as black Migratory forms use countershaded silvery colours On their bellies they often display photophores producing low grade light For a predator from below looking upwards this bioluminescence camouflages the silhouette of the fish However some of these predators have yellow lenses that filter the red deficient ambient light leaving the bioluminescence visible 22 Bathyal edit Main articles Bathyal zone and Bathypelagic fish nbsp Gulper eels use their mouth like a net to catch prey and have a bioluminescent tail to attract prey The bathyl zone is the lower section of the midwater zone and encompasses the depths of 1 000 to 4 000 metres 3 300 to 13 100 ft 23 Light does not reach this zone giving it its nickname the midnight zone due to the lack of light it is less densely populated than the epipelagic zone despite being much larger 24 Fish find it hard to live in this zone as there is crushing pressure cold temperatures of 4 C 39 F a low level of dissolved oxygen and a lack of sufficient nutrients 20 585 What little energy is available in the bathypelagic zone filters from above in the form of detritus faecal material and the occasional invertebrate or mesopelagic fish 20 594 About 20 of the food that has its origins in the epipelagic zone falls down to the mesopelagic zone but only about 5 filters down to the bathypelagic zone 25 The fish that do live there may have reduced or completely lost their gills kidneys hearts and swimbladders have slimy instead of scaly skin and have a weak skeletal and muscular build 20 587 This lack of ossification is an adaptation to save energy when food is scarce 26 Most of the animals that live in the bathyl zone are invertebrates such as sea sponges cephalopods and echinoderms With the exception of very deep areas of the ocean the bathyl zone usually reaches the benthic zone on the seafloor 24 Abyssal and hadal edit Main articles Abyssal plain Abyssal zone and Hadal zone nbsp Giant tube worms chemosynthesize near hydrothermal ventsThe abyssal zone remains in perpetual darkness at a depth of 4 000 to 6 000 metres 13 000 to 20 000 ft 23 The only organisms that inhabit this zone are chemotrophs and predators that can withstand immense pressures sometimes as high as 76 megapascals 750 atm 11 000 psi The hadal zone named after Hades the Greek god of the underworld is a zone designated for the deepest trenches in the world reaching depths of below 6 000 metres 20 000 ft The deepest point in the hadal zone is the Marianas Trench which descends to 10 911 metres 35 797 ft and has a pressure of 110 megapascals 1 100 atm 16 000 psi 27 28 29 Energy sources edit nbsp Wood fall as an energy source Marine snow edit The upper photic zone of the ocean is filled with particle organic matter POM and is quite productive especially in the coastal areas and the upwelling areas However most POM is small and light It may take hundreds or even thousands of years for these particles to settle through the water column into the deep ocean This time delay is long enough for the particles to be remineralized and taken up by organisms in the food webs Scientists at Woods Hole Oceanographic Institution conducted an experiment three decades ago in deep Sargasso Sea looking at the rate of sinking 30 They found what became known as marine snow in which the POM are repackaged into much larger particles which sink at much greater speed falling like snow Because of the sparsity of food the organisms living on and in the bottom are generally opportunistic They have special adaptations for this extreme environment rapid growth effect larval dispersal mechanism and the ability to use a transient food resource One typical example is wood boring bivalves which bore into wood and other plant remains and are fed on the organic matter from the remains Whale falls edit For the deep sea ecosystem the death of a whale is the most important event A dead whale can bring hundreds of tons of organic matter to the bottom Whale fall community progresses through three stages 31 Mobile scavenger stage Big and mobile deep sea animals arrive at the site almost immediately after whales fall on the bottom Amphipods crabs sleeper sharks and hagfish are all scavengers Opportunistic stage Organisms arrive which colonize the bones and surrounding sediments that have been contaminated with organic matter from the carcass and any other tissue left by the scavengers One genus is Osedax 32 a tube worm The larva is born without sex The surrounding environment determines the sex of the larva When a larva settles on a whale bone it turns into a female when a larva settles on or in a female it turns into a dwarf male One female Osedax can carry more than 200 of these male individuals in its oviduct Sulfophilic stage Further decomposition of bones and seawater sulfate reduction happen at this stage Bacteria create a sulphide rich environment analogous to hydrothermal vents Polynoids bivalves gastropods and other sulphur loving creatures move in Chemosynthesis edit Hydrothermal vents edit nbsp hydrothermal ventHydrothermal vents were discovered in 1977 by scientists from Scripps Institution of Oceanography So far the discovered hydrothermal vents are all located at the boundaries of plates East Pacific California Mid Atlantic ridge China and Japan New ocean basin material is being made in regions such as the Mid Atlantic ridge as tectonic plates pull away from each other The rate of spreading of plates is 1 5 cm yr Cold sea water circulates down through cracks between two plates and heats up as it passes through hot rock Minerals and sulfides are dissolved into the water during the interaction with rock Eventually the hot solutions emanate from an active sub seafloor rift creating a hydrothermal vent Chemosynthesis of bacteria provide the energy and organic matter for the whole food web in vent ecosystems These vents spew forth very large amounts of chemicals which these bacteria can transform into energy These bacteria can also grow free of a host and create mats of bacteria on the sea floor around hydrothermal vents where they serve as food for other creatures Bacteria are a key energy source in the food chain This source of energy creates large populations in areas around hydrothermal vents which provides scientists with an easy stop for research Organisms can also use chemosynthesis to attract prey or to attract a mate 33 Giant tube worms can grow to 2 4 m 7 ft 10 in tall because of the richness of nutrients Over 300 new species have been discovered at hydrothermal vents 34 Hydrothermal vents are entire ecosystems independent from sunlight and may be the first evidence that the earth can support life without the sun Cold seeps edit A cold seep sometimes called a cold vent is an area of the ocean floor where hydrogen sulfide methane and other hydrocarbon rich fluid seepage occurs often in the form of a brine pool Ecology editDeep sea food webs are complex and aspects of the system are poorly understood Typically predator prey interactions within the deep are compiled by direct observation likely from remotely operated underwater vehicles analysis of stomach contents and biochemical analysis Stomach content analysis is the most common method used but it is not reliable for some species 35 In deep sea pelagic ecosystems off of California the trophic web is dominated by deep sea fishes cephalopods gelatinous zooplankton and crustaceans Between 1991 and 2016 242 unique feeding relationships between 166 species of predators and prey demonstrated that gelatinous zooplankton have an ecological impact similar to that of large fishes and squid Narcomedusae siphonophores of the family Physonectae ctenophores and cephalopods consumed the greatest diversity of prey in decreasing order 35 Cannibalism has been documented in squid of the genus Gonatus 36 Deep sea research edit nbsp Alvin in 1978 a year after it first explored a hydrothermal vent Humans have explored less than 4 of the ocean floor and dozens of new species of deep sea creatures are discovered with every dive The submarine DSV Alvin owned by the US Navy and operated by the Woods Hole Oceanographic Institution WHOI in Woods Hole Massachusetts exemplifies the type of craft used to explore deep water This 16 ton submarine can withstand extreme pressure and is easily manoeuvrable despite its weight and size The extreme difference in pressure between the sea floor and the surface makes creatures survival on the surface near impossible this makes in depth research difficult because most useful information can only be found while the creatures are alive Recent developments have allowed scientists to look at these creatures more closely and for a longer time Marine biologist Jeffery Drazen has explored a solution a pressurized fish trap This captures a deep water creature and adjusts its internal pressure slowly to surface level as the creature is brought to the surface in the hope that the creature can adjust 37 Another scientific team from the Universite Pierre et Marie Curie has developed a capture device known as the PERISCOP which maintains water pressure as it surfaces thus keeping the samples in a pressurized environment during the ascent This permits close study on the surface without any pressure disturbances affecting the sample 38 See also edit nbsp Oceans portalDeep sea fish Movile CaveReferences edit a b Minerals Management Service Gulf of Mexico OCS Region November 2006 Gulf of Mexico OCS Oil and Gas Lease Sales 2007 2012 Western Planning Area Sales 204 207 210 215 and 218 Central Planning Area Sales 205 206 208 213 216 and 222 Draft Environmental Impact Statement Volume I Chapters 1 8 and Appendices U S Department of the Interior Minerals Management Service Gulf of Mexico OCS Region New Orleans page 3 27 PDF Archived 2009 03 26 at the Wayback Machine Robot sub reaches deepest ocean BBC News 3 June 2009 Retrieved 2009 06 03 a b University of Hawaii Marine Center 4 June 2009 Daily Reports for R V KILO MOANA June amp July 2009 Honolulu Hawaii University of Hawaii Archived from the original on 19 September 2009 Retrieved 24 June 2010 University of Hawaii Marine Center 4 June 2009 Inventory of Scientific Equipment aboard the R V KILO MOANA Honolulu Hawaii University of Hawaii Archived from the original on 13 June 2010 Retrieved 18 June 2010 a b K L Smith Jr H A Ruhl B J Bett D S M Billett R S Lampitt R S Kaufmann 17 November 2009 Climate carbon cycling and deep ocean ecosystems PNAS 106 46 19211 19218 Bibcode 2009PNAS 10619211S doi 10 1073 pnas 0908322106 PMC 2780780 PMID 19901326 a b c d Jorge Csirke 1997 II The Limits of Marine Productivity PDF In Edward A Laws ed El Nino and the Peruvian Anchovy Fishery series Global Change Instruction Program Vol 9 Sausalito University Science Books pp 118 121 doi 10 1023 A 1008801515441 ISBN 978 0 935702 80 4 S2CID 29314639 Archived from the original PDF on 10 June 2011 Retrieved 18 June 2010 a href Template Cite book html title Template Cite book cite book a journal ignored help a b Photic zone Encyclopaedia Britannica 2010 Retrieved 18 June 2010 a b c d Jeananda Col 2004 Twilight Ocean Disphotic Zone EnchantedLearning com Retrieved 18 June 2010 a b c Ken O Buesseler Carl H Lamborg Philip W Boyd Phoebe J Lam et al 27 April 2007 Revisiting Carbon Flux Through the Ocean s Twilight Zone Science 316 5824 567 570 Bibcode 2007Sci 316 567B CiteSeerX 10 1 1 501 2668 doi 10 1126 science 1137959 PMID 17463282 S2CID 8423647 National Oceanic and Atmospheric Administration 2 December 2008 How deep is the ocean Washington DC National Oceanic and Atmospheric Administration Retrieved 19 June 2010 The Deep Sea at MarineBio org Ocean biology Marine life Sea creatures Marine conservation Nybakken James W Marine Biology An Ecological Approach Fifth Edition Benjamin Cummings 2001 p 136 141 Paul R Pinet 1996 Invitation to Oceanography 3rd ed St Paul MN West Publishing Co p 202 ISBN 978 0 314 06339 7 Pinet 1996 p 206 Pinet 1996 pp 206 207 Pinet 1996 p 207 NOAA exploration of a brine pool Midwater zone Aquatic Life of the World Vol 6 Tarrytown New York Marshall Cavendish Corporation 2001 pp 340 341 ISBN 978 0 7614 7176 9 Bone Quentin Moore Richard 2008 Biology of Fishes Garland Science p 38 ISBN 978 0 203 88522 2 a b c d e Moyle P B Cech J J 2004 Fishes An Introduction to Ichthyology 5 ed Benjamin Cummings ISBN 978 0 13 100847 2 Douglas E Friedl W Pickwell G 1976 Fishes in oxygen minimum zones Blood oxygenation characteristics Science 191 4230 957 9 Bibcode 1976Sci 191 957D doi 10 1126 science 1251208 PMID 1251208 Muntz W R A 2009 On yellow lenses in mesopelagic animals Journal of the Marine Biological Association of the United Kingdom 56 4 963 976 doi 10 1017 S0025315400021019 S2CID 86353657 a b Bathypelagic zone Layers of the ocean National Weather Service Archived from the original on 7 February 2017 Retrieved 1 January 2021 a href Template Cite web html title Template Cite web cite web a CS1 maint bot original URL status unknown link a b Enig C C 1997 Research on marine benthos Spanish Institute of Oceanography in Spanish Madrid Ministry of Agriculture pp 23 33 ISBN 978 84 491 0299 8 Ryan Paddy 21 September 2007 Deep sea creatures The bathypelagic zone Te Ara the Encyclopedia of New Zealand Retrieved 4 September 2016 Yancey Paul H Gerringer Mackenzie E Drazen Jeffrey C Rowden Ashley A Jamieson Alan 2014 03 25 Marine fish may be biochemically constrained from inhabiting the deepest ocean depths Proceedings of the National Academy of Sciences 111 12 4461 4465 Bibcode 2014PNAS 111 4461Y doi 10 1073 pnas 1322003111 ISSN 0027 8424 PMC 3970477 PMID 24591588 NOAA Ocean Explorer History Quotations Soundings Sea Bottom and Geophysics NOAA Office of Ocean Exploration and Research Retrieved 4 September 2016 Smith Craig R de Leo Fabio C Bernardino Angelo F Sweetman Andrew K Arbizu Pedro Martinez 2008 Abyssal food limitation ecosystem structure and climate change PDF Trends in Ecology and Evolution 23 9 518 528 doi 10 1016 j tree 2008 05 002 PMID 18584909 Archived from the original PDF on 2011 07 20 Retrieved 2016 09 04 Vinogradova N G 1997 Zoogeography of the Abyssal and Hadal Zones The Biogeography of the Oceans Advances in Marine Biology Vol 32 pp 325 387 doi 10 1016 S0065 2881 08 60019 X ISBN 978 0 12 026132 1 Marine Snow and Fecal Pellets Shana Goffredi Unusual benthic fauna associated with a whale fall in Monterey Canyon California Deep Sea Research 1295 1304 2004 Noah K Whiteman Between a whale bone and the deep blue sea the provenance of dwarf males in whale bone eating tube worms Molecular Ecology 4395 4397 2008 Chemosynthesis Botos Sonia Life on a hydrothermal vent a b Choy C Anela Haddock Steven H D Robison Bruce H 2017 12 06 Deep pelagic food web structure as revealed by in situ feeding observations Proc R Soc B 284 1868 20172116 doi 10 1098 rspb 2017 2116 PMC 5740285 PMID 29212727 Klein JoAnna December 19 2017 What Eats What A Landlubber s Guide to Deep Sea Dining The New York Times ISSN 0362 4331 Archived from the original on December 20 2017 Retrieved 2017 12 20 New Trap May Take Deep Sea Fish Safely Out of the Dark Lever A 31 July 2008 Live fish caught at record depth BBC News Retrieved 18 February 2011 Further reading editKupriyanova E K Vinn O Taylor P D Schopf J W Kudryavtsev A B Bailey Brock J 2014 Serpulids living deep calcareous tubeworms beyond the abyss Deep Sea Research Part I 90 91 104 Bibcode 2014DSRI 90 91K doi 10 1016 j dsr 2014 04 006 Retrieved from https en wikipedia org w index php title Deep sea community amp oldid 1186295115, wikipedia, wiki, book, books, library,

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