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Seabed

January 31, 2023

The seabed (also known as the seafloor, sea floor, ocean floor, and ocean bottom) is the bottom of the ocean. All floors of the ocean are known as 'seabeds'.

The structure of the seabed of the global ocean is governed by plate tectonics. Most of the ocean is very deep, where the seabed is known as the abyssal plain. Seafloor spreading creates mid-ocean ridges along the center line of major ocean basins, where the seabed is slightly shallower than the surrounding abyssal plain. From the abyssal plain, the seabed slopes upward toward the continents and becomes, in order from deep to shallow, the continental rise, slope, and shelf. The depth within the seabed itself, such as the depth down through a sediment core, is known as the “depth below seafloor.” The ecological environment of the seabed and the deepest waters are collectively known, as a habitat for creatures, as the “benthos.”

Most of the seabed throughout the world's oceans is covered in layers of marine sediments. Categorized by where the materials come from or composition, these sediments are classified as either: from land (terrigenous), from biological organisms (biogenous), from chemical reactions (hydrogenous), and from space (cosmogenous). Categorized by size, these sediments range from very small particles called clays and silts, known as mud, to larger particles from sand to boulders.

Features of the seabed are governed by the physics of sediment transport and by the biology of the creatures living in the seabed and in the ocean waters above. Physically, seabed sediments often come from the erosion of material on land and from other rarer sources, such as volcanic ash. Sea currents transport sediments, especially in shallow waters where tidal energy and wave energy cause resuspension of seabed sediments. Biologically, microorganisms living within the seabed sediments change seabed chemistry. Marine organisms create sediments, both within the seabed and in the water above. For example, phytoplankton with silicate or calcium carbonate shells grow in abundance in the upper ocean, and when they die, their shells sink to the seafloor to become seabed sediments.

Human impacts on the seabed are diverse. Examples of human effects on the seabed include exploration, plastic pollution, and exploitation by mining and dredging operations. To map the seabed, ships use acoustic technology to map water depths throughout the world. Submersible vehicles help researchers study unique seabed ecosystems such as hydrothermal vents. Plastic pollution is a global phenomenon, and because the ocean is the ultimate destination for global waterways, much of the world's plastic ends up in the ocean and some sinks to the seabed. Exploitation of the seabed involves extracting valuable minerals from sulfide deposits via deep sea mining, as well as dredging sand from shallow environments for construction and beach nourishment.

Structure

See also: Seafloor spreading
 
Bathymetry of the ocean floor showing the continental shelves and oceanic plateaus (red), the mid-ocean ridges (yellow-green) and the abyssal plains (blue to purple). Like land terrain, the ocean floor has mountains including volcanoes, ridges, valleys, and plains.
 
The major oceanic divisions

Most of the oceans have a common structure, created by common physical phenomena, mainly from tectonic movement, and sediment from various sources. The structure of the oceans, starting with the continents, begins usually with a continental shelf, continues to the continental slope – which is a steep descent into the ocean, until reaching the abyssal plain – a topographic plain, the beginning of the seabed, and its main area. The border between the continental slope and the abyssal plain usually has a more gradual descent, and is called the continental rise, which is caused by sediment cascading down the continental slope.

The mid-ocean ridge, as its name implies, is a mountainous rise through the middle of all the oceans, between the continents. Typically a rift runs along the edge of this ridge. Along tectonic plate edges there are typically oceanic trenches – deep valleys, created by the mantle circulation movement from the mid-ocean mountain ridge to the oceanic trench.[1]

Hotspot volcanic island ridges are created by volcanic activity, erupting periodically, as the tectonic plates pass over a hotspot. In areas with volcanic activity and in the oceanic trenches there are hydrothermal vents – releasing high pressure and extremely hot water and chemicals into the typically freezing water around it.

Deep ocean water is divided into layers or zones, each with typical features of salinity, pressure, temperature and marine life, according to their depth. Lying along the top of the abyssal plain is the abyssal zone, whose lower boundary lies at about 6,000 m (20,000 ft). The hadal zone – which includes the oceanic trenches, lies between 6,000 and 11,000 metres (20,000–36,000 ft) and is the deepest oceanic zone.[2][3]

Depth below seafloor

Depth below seafloor is a vertical coordinate used in geology, paleontology, oceanography, and petrology (see ocean drilling). The acronym "mbsf" (meaning "meters below the seafloor") is a common convention used for depths below the seafloor.[4][5]

  • Different seabeds in the world’s oceans
  •  

    gravel seabed in Italy

  •  

    white sand seabed in Mexico

  •  

    sand seabed in Greece

  •  

    hydrothermal vents

Sediments

Main article: Marine sediment
 
Total sediment thickness of the world's oceans and continental margins in meters.

Sediments in the seabed vary in origin, from eroded land materials carried into the ocean by rivers or wind flow, waste and decompositions of sea creatures, and precipitation of chemicals within the sea water itself, including some from outer space.[6] There are four basic types of sediment of the sea floor:

  1. Terrigenous (also lithogenous) describes the sediment from continents eroded by rain, rivers, and glaciers, as well as sediment blown into the ocean by the wind, such as dust and volcanic ash.
  2. Biogenous material is the sediment made up of the hard parts of sea creatures, mainly phytoplankton, that accumulate on the bottom of the ocean.
  3. Hydrogenous sediment is material that precipitates in the ocean when oceanic conditions change, or material created in hydrothermal vent systems.
  4. Cosmogenous sediment comes from extraterrestrial sources.[7]

Terrigenous and biogenous

 
Satellite image of wind-blown mineral dust over the Atlantic. Dust may become terrigenous sediment on the seabed.
 
Phytoplankton grow shells which later sink to the seabed to become biogenous sediments. For example, diatoms make silicate shells, which become siliceous ooze.

Terrigenous sediment is the most abundant sediment found on the seafloor. Terrigenous sediments come from the continents. These materials are eroded from continents and transported by wind and water to the ocean. Fluvial sediments are transported from land by rivers and glaciers, such as clay, silt, mud, and glacial flour. Aeolian sediments are transported by wind, such as dust and volcanic ash.[8]

Biogenous sediment is the next most abundant material on the seafloor. Biogenous sediments are biologically produced by living creatures. Sediments made up of at least 30% biogenous material are called "oozes." There are two types of oozes: Calcareous oozes and Siliceous oozes. Plankton grow in ocean waters and create the materials that become oozes on the seabed. Calcareous oozes are predominantly composed of calcium shells found in phytoplankton such as coccolithophores and zooplankton like the foraminiferans. These calcareous oozes are never found deeper than about 4,000 to 5,000 meters because at further depths the calcium dissolves.[9] Similarly, Siliceous oozes are dominated by the siliceous shells of phytoplankton like diatoms and zooplankton such as radiolarians. Depending on the productivity of these planktonic organisms, the shell material that collects when these organisms die may build up at a rate anywhere from 1 mm to 1 cm every 1000 years.[9]

Hydrogenous and cosmogenous

 
Hydrothermal vent fluids cause chemical reactions that precipitate out minerals that form sediments on the surrounding seafloor.

Hydrogenous sediments are uncommon. They only occur with changes in oceanic conditions such as temperature and pressure. Rarer still are cosmogenous sediments. Hydrogenous sediments are formed from dissolved chemicals that precipitate from the ocean water, or along the mid-ocean ridges, they can form by metallic elements binding onto rocks that have water of more than 300 °C circulating around them. When these elements mix with the cold sea water they precipitate from the cooling water.[9] Known as manganese nodules, they are composed of layers of different metals like manganese, iron, nickel, cobalt, and copper, and they are always found on the surface of the ocean floor.[9]

Cosmogenous sediments are the remains of space debris such as comets and asteroids, made up of silicates and various metals that have impacted the Earth.[10]

Size classification

 
Sediment types from the Southern Ocean showing many different grain sizes: A) gravel and sand, B) gravel, C) bioturbated mud and sand, and D) laminated clays and silts.[11]

Another way that sediments are described is through their descriptive classification. These sediments vary in size, anywhere from 1/4096 of a mm to greater than 256 mm. The different types are: boulder, cobble, pebble, granule, sand, silt, and clay, each type becoming finer in grain. The grain size indicates the type of sediment and the environment in which it was created. Larger grains sink faster and can only be pushed by rapid flowing water (high energy environment) whereas small grains sink very slowly and can be suspended by slight water movement, accumulating in conditions where water is not moving so quickly.[12] This means that larger grains of sediment may come together in higher energy conditions and smaller grains in lower energy conditions.

Benthos

This section is an excerpt from Benthos.[edit]
 
Seaweed and two chitons in a tide pool

Benthos (from Ancient Greek βένθος (bénthos) 'the depths (of the sea)'), also known as benthon, is the community of organisms that live on, in, or near the bottom of a sea, river, lake, or stream, also known as the benthic zone.[13] This community lives in or near marine or freshwater sedimentary environments, from tidal pools along the foreshore, out to the continental shelf, and then down to the abyssal depths.

Many organisms adapted to deep-water pressure cannot survive in the upper parts of the water column. The pressure difference can be very significant (approximately one atmosphere for every 10 metres of water depth).[14]

Because light is absorbed before it can reach deep ocean water, the energy source for deep benthic ecosystems is often organic matter from higher up in the water column that drifts down to the depths. This dead and decaying matter sustains the benthic food chain; most organisms in the benthic zone are scavengers or detritivores.

The term benthos, coined by Haeckel in 1891,[15] comes from the Greek noun βένθος 'depth of the sea'.[13][16] Benthos is used in freshwater biology to refer to organisms at the bottom of freshwater bodies of water, such as lakes, rivers, and streams.[17] There is also a redundant synonym, Benton.[18]

Topography

See also: Bathymetry and Ocean surface topography

Seabed topography (ocean topography or marine topography) refers to the shape of the land (topography) when it interfaces with the ocean. These shapes are obvious along coastlines, but they occur also in significant ways underwater. The effectiveness of marine habitats is partially defined by these shapes, including the way they interact with and shape ocean currents, and the way sunlight diminishes when these landforms occupy increasing depths. Tidal networks depend on the balance between sedimentary processes and hydrodynamics however, anthropogenic influences can impact the natural system more than any physical driver.[19]

Marine topographies include coastal and oceanic landforms ranging from coastal estuaries and shorelines to continental shelves and coral reefs. Further out in the open ocean, they include underwater and deep sea features such as ocean rises and seamounts. The submerged surface has mountainous features, including a globe-spanning mid-ocean ridge system, as well as undersea volcanoes,[20] oceanic trenches, submarine canyons, oceanic plateaus and abyssal plains.

The mass of the oceans is approximately 1.35×1018 metric tons, or about 1/4400 of the total mass of the Earth. The oceans cover an area of 3.618×108 km2 with a mean depth of 3,682 m, resulting in an estimated volume of 1.332×109 km3.[21]

Features

 
Layers of the pelagic zone

Each region of the seabed has typical features such as common sediment composition, typical topography, salinity of water layers above it, marine life, magnetic direction of rocks, and sedimentation. Some features of the seabed include flat abyssal plains, mid-ocean ridges, deep trenches, and hydrothermal vents.

Seabed topography is flat where layers of sediments cover the tectonic features. For example, the abyssal plain regions of the ocean are relatively flat and covered in many layers of sediments.[22] Sediments in these flat areas come from various sources, including but not limited to: land erosion sediments from rivers, chemically precipitated sediments from hydrothermal vents, Microorganism activity, sea currents eroding the seabed and transporting sediments to the deeper ocean, and phytoplankton shell materials.

Where the seafloor is actively spreading and sedimentation is relatively light, such as in the northern and eastern Atlantic Ocean, the original tectonic activity can be clearly seen as straight line "cracks" or "vents" thousands of kilometers long. These underwater mountain ranges are known as mid-ocean ridges.[7]

Other seabed environments include hydrothermal vents, cold seeps, and shallow areas. Marine life is abundant in the deep sea around hydrothermal vents.[23] Large deep sea communities of marine life have been discovered around black and white smokers — vents emitting chemicals toxic to humans and most vertebrates. This marine life receives its energy both from the extreme temperature difference (typically a drop of 150 degrees) and from chemosynthesis by bacteria. Brine pools are another seabed feature,[24] usually connected to cold seeps. In shallow areas, the seabed can host sediments created by marine life such as corals, fish, algae, crabs, marine plants and other organisms.

Human impact

Exploration

Main articles: Deep-sea exploration and Oceanography § History
A video describing the operation and use of an autonomous lander in deep sea research.

The seabed has been explored by submersibles such as Alvin and, to some extent, scuba divers with special equipment. Hydrothermal vents were discovered by an underwater camera platform by researchers in 1977.[23] In recent years satellite measurements of ocean surface topography show very clear maps of the seabed,[25] and these satellite-derived maps are used extensively in the study and exploration of the ocean floor.

Plastic pollution

In 2020 scientists created what may be the first scientific estimate of how much microplastic currently resides in Earth's seafloor, after investigating six areas of ~3 km depth ~300 km off the Australian coast. They found the highly variable microplastic counts to be proportionate to plastic on the surface and the angle of the seafloor slope. By averaging the microplastic mass per cm3, they estimated that Earth's seafloor contains ~14 million tons of microplastic – about double the amount they estimated based on data from earlier studies – despite calling both estimates "conservative" as coastal areas are known to contain much more microplastic pollution. These estimates are about one to two times the amount of plastic thought – per Jambeck et al., 2015 – to currently enter the oceans annually.[26][27][28]

Exploitation

This section is an excerpt from Deep sea mining.[edit]
 
Schematic of a polymetallic nodule mining operation. From top to bottom, the three zoom-in panels illustrate the surface operation vessel, the midwater sediment plume, and the nodule collector operating on the seabed. The midwater plume comprises two stages: (i) the dynamic plume, in which the sediment-laden discharge water rapidly descends and dilutes to a neutral buoyancy depth, and (ii) the subsequent ambient plume that is advected by the ocean current and subject to background turbulence and settling. (MIT/2021)

Deep sea mining is a growing subfield of experimental seabed mining that involves the retrieval of minerals and deposits from the ocean floor found at depths of 200 metres (660 ft) or greater.[29][30] As of 2021, the majority of marine mining efforts are limited to shallow coastal waters only, where sand, tin and diamonds are more readily accessible.[31] There are three types of deep sea mining that have generated great interest: polymetallic nodule mining, polymetallic sulphide mining, and the mining of cobalt-rich ferromanganese crusts.[32] The majority of proposed deep sea mining sites are near of polymetallic nodules or active and extinct hydrothermal vents at 1,400 to 3,700 metres (4,600 to 12,100 ft) below the ocean’s surface.[33] The vents create globular or massive sulfide deposits, which contain valuable metals such as silver, gold, copper, manganese, cobalt, and zinc.[34][35] The deposits are mined using either hydraulic pumps or bucket systems that take ore to the surface to be processed.

Marine minerals include sea-dredged and seabed minerals. Sea-dredged minerals are normally extracted by dredging operations within coastal zones, to maximum sea depths of about 200 m. Minerals normally extracted from these depths include sand, silt and mud for construction purposes, mineral rich sands such as ilmenite and diamonds.[36]

As with all mining operations, deep sea mining raises questions about its environmental impact. There is a growing debate about whether deep sea mining should be allowed.[37] Environmental advocacy groups such as Greenpeace and the Deep Sea Mining Campaign[38] have argued that seabed mining should not be permitted in most of the world's oceans because of the potential for damage to deep sea ecosystems and pollution by heavy metal-laden plumes.[34] Prominent environmental activists and state leaders have also called for moratoriums or total bans due to the potential of devastating environmental impacts.[39][40] Some argue that there should be a total ban on seabed mining.[41] Some anti-seabed mining campaigns have won the support of large industry such as some of the technology giants, and large car companies. However, these same companies will be increasingly reliant on the metals seabed minerals can provide. Some scientists argue that seabed mining should not go ahead, as we know such a relatively small amount about the biodiversity of the deep ocean environment.[42] Individual countries[which?] with significant deposits of seabed minerals within their large EEZ’s are making their own decisions pertaining to seabed mining, exploring ways of undertaking seabed mining without causing too much damage to the deep ocean environment,[43] or deciding not to develop seabed mines.[44] Some companies are attempting to build polymetallic deep sea mining equipment which does no serious harm and preservers the marine habitat.[45]

As of 2022 there was no commercial mining of seabed minerals. However, the International Seabed Authority has granted 19 exploration licenses for polymetallic nodules, within the Clarion Clipperton Zone.[46] [47] The Cook Islands Seabed Minerals Authority (SBMA) has granted 3 exploration licenses for polymetallic nodules within their EEZ.[48]

There is the potential for mining at a range of scales within the oceans from small to very large. Technologies involved in the mining of seabed minerals would be highly technological, and involve a range of robotic mining machines, as well as surface ships, and metal refineries at onshore locations. One vision for the post-fossil fuel world will rely on wind farms, solar energy, electric cars, and improved battery technologies: these use a high volume and wide range of metallic commodities including ‘green’ or ‘critical’ metals many of which are in relatively short supply. Seabed mining could provide a near-term solution to the provision of many of these metals, though only serves to worsen the fundamental problems posed by extraction.[49][50]

In art and culture

Some children's play songs include elements such as "There's a hole at the bottom of the sea", or "A sailor went to sea... but all that he could see was the bottom of the deep blue sea".

On and under the seabed are archaeological sites of historic interest, such as shipwrecks and sunken towns. This underwater cultural heritage is protected by the UNESCO Convention on the Protection of the Underwater Cultural Heritage. The convention aims at preventing looting and the destruction or loss of historic and cultural information by providing an international legal framework.[51]

See also

References

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Further reading

External links

 
Look up seabed in Wiktionary, the free dictionary.
  • Understanding the Seafloor presentation from Cosee – the Center for Ocean Sciences Educational Excellence.
  • Ocean Explorer (www.oceanexplorer.noaa.gov) – Public outreach site for explorations sponsored by the Office of Ocean Exploration.
  • NOAA, Ocean Explorer Gallery, Submarine Ring of Fire 2006 Gallery, Submarine Ring of Fire 2004 Gallery – A rich collection of images, video, audio and podcast.
  • NOAA, Ocean Explorer YouTube Channel
  • Submarine Ring of Fire, Mariana Arc – Explore the volcanoes of the Mariana Arc, Submarine Ring of Fire.
  • Age of the Ocean Floor National Geophysical Data Center
  • Astonishing deep sea life on TED (conference)

January 31, 2023
seabed, seabed, also, known, seafloor, floor, ocean, floor, ocean, bottom, bottom, ocean, floors, ocean, known, seabeds, structure, seabed, global, ocean, governed, plate, tectonics, most, ocean, very, deep, where, seabed, known, abyssal, plain, seafloor, spre. The seabed also known as the seafloor sea floor ocean floor and ocean bottom is the bottom of the ocean All floors of the ocean are known as seabeds The structure of the seabed of the global ocean is governed by plate tectonics Most of the ocean is very deep where the seabed is known as the abyssal plain Seafloor spreading creates mid ocean ridges along the center line of major ocean basins where the seabed is slightly shallower than the surrounding abyssal plain From the abyssal plain the seabed slopes upward toward the continents and becomes in order from deep to shallow the continental rise slope and shelf The depth within the seabed itself such as the depth down through a sediment core is known as the depth below seafloor The ecological environment of the seabed and the deepest waters are collectively known as a habitat for creatures as the benthos Most of the seabed throughout the world s oceans is covered in layers of marine sediments Categorized by where the materials come from or composition these sediments are classified as either from land terrigenous from biological organisms biogenous from chemical reactions hydrogenous and from space cosmogenous Categorized by size these sediments range from very small particles called clays and silts known as mud to larger particles from sand to boulders Features of the seabed are governed by the physics of sediment transport and by the biology of the creatures living in the seabed and in the ocean waters above Physically seabed sediments often come from the erosion of material on land and from other rarer sources such as volcanic ash Sea currents transport sediments especially in shallow waters where tidal energy and wave energy cause resuspension of seabed sediments Biologically microorganisms living within the seabed sediments change seabed chemistry Marine organisms create sediments both within the seabed and in the water above For example phytoplankton with silicate or calcium carbonate shells grow in abundance in the upper ocean and when they die their shells sink to the seafloor to become seabed sediments Human impacts on the seabed are diverse Examples of human effects on the seabed include exploration plastic pollution and exploitation by mining and dredging operations To map the seabed ships use acoustic technology to map water depths throughout the world Submersible vehicles help researchers study unique seabed ecosystems such as hydrothermal vents Plastic pollution is a global phenomenon and because the ocean is the ultimate destination for global waterways much of the world s plastic ends up in the ocean and some sinks to the seabed Exploitation of the seabed involves extracting valuable minerals from sulfide deposits via deep sea mining as well as dredging sand from shallow environments for construction and beach nourishment Contents 1 Structure 1 1 Depth below seafloor 2 Sediments 2 1 Terrigenous and biogenous 2 2 Hydrogenous and cosmogenous 2 3 Size classification 3 Benthos 4 Topography 5 Features 6 Human impact 6 1 Exploration 6 2 Plastic pollution 6 3 Exploitation 6 4 In art and culture 7 See also 8 References 9 Further reading 10 External linksStructure EditSee also Seafloor spreading Bathymetry of the ocean floor showing the continental shelves and oceanic plateaus red the mid ocean ridges yellow green and the abyssal plains blue to purple Like land terrain the ocean floor has mountains including volcanoes ridges valleys and plains The major oceanic divisions Most of the oceans have a common structure created by common physical phenomena mainly from tectonic movement and sediment from various sources The structure of the oceans starting with the continents begins usually with a continental shelf continues to the continental slope which is a steep descent into the ocean until reaching the abyssal plain a topographic plain the beginning of the seabed and its main area The border between the continental slope and the abyssal plain usually has a more gradual descent and is called the continental rise which is caused by sediment cascading down the continental slope The mid ocean ridge as its name implies is a mountainous rise through the middle of all the oceans between the continents Typically a rift runs along the edge of this ridge Along tectonic plate edges there are typically oceanic trenches deep valleys created by the mantle circulation movement from the mid ocean mountain ridge to the oceanic trench 1 Hotspot volcanic island ridges are created by volcanic activity erupting periodically as the tectonic plates pass over a hotspot In areas with volcanic activity and in the oceanic trenches there are hydrothermal vents releasing high pressure and extremely hot water and chemicals into the typically freezing water around it Deep ocean water is divided into layers or zones each with typical features of salinity pressure temperature and marine life according to their depth Lying along the top of the abyssal plain is the abyssal zone whose lower boundary lies at about 6 000 m 20 000 ft The hadal zone which includes the oceanic trenches lies between 6 000 and 11 000 metres 20 000 36 000 ft and is the deepest oceanic zone 2 3 Depth below seafloor Edit Depth below seafloor is a vertical coordinate used in geology paleontology oceanography and petrology see ocean drilling The acronym mbsf meaning meters below the seafloor is a common convention used for depths below the seafloor 4 5 Different seabeds in the world s oceans gravel seabed in Italy white sand seabed in Mexico sand seabed in Greece hydrothermal ventsSediments EditMain article Marine sediment Total sediment thickness of the world s oceans and continental margins in meters Sediments in the seabed vary in origin from eroded land materials carried into the ocean by rivers or wind flow waste and decompositions of sea creatures and precipitation of chemicals within the sea water itself including some from outer space 6 There are four basic types of sediment of the sea floor Terrigenous also lithogenous describes the sediment from continents eroded by rain rivers and glaciers as well as sediment blown into the ocean by the wind such as dust and volcanic ash Biogenous material is the sediment made up of the hard parts of sea creatures mainly phytoplankton that accumulate on the bottom of the ocean Hydrogenous sediment is material that precipitates in the ocean when oceanic conditions change or material created in hydrothermal vent systems Cosmogenous sediment comes from extraterrestrial sources 7 Terrigenous and biogenous Edit Satellite image of wind blown mineral dust over the Atlantic Dust may become terrigenous sediment on the seabed Phytoplankton grow shells which later sink to the seabed to become biogenous sediments For example diatoms make silicate shells which become siliceous ooze Terrigenous sediment is the most abundant sediment found on the seafloor Terrigenous sediments come from the continents These materials are eroded from continents and transported by wind and water to the ocean Fluvial sediments are transported from land by rivers and glaciers such as clay silt mud and glacial flour Aeolian sediments are transported by wind such as dust and volcanic ash 8 Biogenous sediment is the next most abundant material on the seafloor Biogenous sediments are biologically produced by living creatures Sediments made up of at least 30 biogenous material are called oozes There are two types of oozes Calcareous oozes and Siliceous oozes Plankton grow in ocean waters and create the materials that become oozes on the seabed Calcareous oozes are predominantly composed of calcium shells found in phytoplankton such as coccolithophores and zooplankton like the foraminiferans These calcareous oozes are never found deeper than about 4 000 to 5 000 meters because at further depths the calcium dissolves 9 Similarly Siliceous oozes are dominated by the siliceous shells of phytoplankton like diatoms and zooplankton such as radiolarians Depending on the productivity of these planktonic organisms the shell material that collects when these organisms die may build up at a rate anywhere from 1 mm to 1 cm every 1000 years 9 Hydrogenous and cosmogenous Edit Hydrothermal vent fluids cause chemical reactions that precipitate out minerals that form sediments on the surrounding seafloor Hydrogenous sediments are uncommon They only occur with changes in oceanic conditions such as temperature and pressure Rarer still are cosmogenous sediments Hydrogenous sediments are formed from dissolved chemicals that precipitate from the ocean water or along the mid ocean ridges they can form by metallic elements binding onto rocks that have water of more than 300 C circulating around them When these elements mix with the cold sea water they precipitate from the cooling water 9 Known as manganese nodules they are composed of layers of different metals like manganese iron nickel cobalt and copper and they are always found on the surface of the ocean floor 9 Cosmogenous sediments are the remains of space debris such as comets and asteroids made up of silicates and various metals that have impacted the Earth 10 Size classification Edit Sediment types from the Southern Ocean showing many different grain sizes A gravel and sand B gravel C bioturbated mud and sand and D laminated clays and silts 11 Another way that sediments are described is through their descriptive classification These sediments vary in size anywhere from 1 4096 of a mm to greater than 256 mm The different types are boulder cobble pebble granule sand silt and clay each type becoming finer in grain The grain size indicates the type of sediment and the environment in which it was created Larger grains sink faster and can only be pushed by rapid flowing water high energy environment whereas small grains sink very slowly and can be suspended by slight water movement accumulating in conditions where water is not moving so quickly 12 This means that larger grains of sediment may come together in higher energy conditions and smaller grains in lower energy conditions Benthos EditThis section is an excerpt from Benthos edit Seaweed and two chitons in a tide pool Benthos from Ancient Greek ben8os benthos the depths of the sea also known as benthon is the community of organisms that live on in or near the bottom of a sea river lake or stream also known as the benthic zone 13 This community lives in or near marine or freshwater sedimentary environments from tidal pools along the foreshore out to the continental shelf and then down to the abyssal depths Many organisms adapted to deep water pressure cannot survive in the upper parts of the water column The pressure difference can be very significant approximately one atmosphere for every 10 metres of water depth 14 Because light is absorbed before it can reach deep ocean water the energy source for deep benthic ecosystems is often organic matter from higher up in the water column that drifts down to the depths This dead and decaying matter sustains the benthic food chain most organisms in the benthic zone are scavengers or detritivores The term benthos coined by Haeckel in 1891 15 comes from the Greek noun ben8os depth of the sea 13 16 Benthos is used in freshwater biology to refer to organisms at the bottom of freshwater bodies of water such as lakes rivers and streams 17 There is also a redundant synonym Benton 18 Topography EditSee also Bathymetry and Ocean surface topography Seabed topography ocean topography or marine topography refers to the shape of the land topography when it interfaces with the ocean These shapes are obvious along coastlines but they occur also in significant ways underwater The effectiveness of marine habitats is partially defined by these shapes including the way they interact with and shape ocean currents and the way sunlight diminishes when these landforms occupy increasing depths Tidal networks depend on the balance between sedimentary processes and hydrodynamics however anthropogenic influences can impact the natural system more than any physical driver 19 Marine topographies include coastal and oceanic landforms ranging from coastal estuaries and shorelines to continental shelves and coral reefs Further out in the open ocean they include underwater and deep sea features such as ocean rises and seamounts The submerged surface has mountainous features including a globe spanning mid ocean ridge system as well as undersea volcanoes 20 oceanic trenches submarine canyons oceanic plateaus and abyssal plains The mass of the oceans is approximately 1 35 1018 metric tons or about 1 4400 of the total mass of the Earth The oceans cover an area of 3 618 108 km2 with a mean depth of 3 682 m resulting in an estimated volume of 1 332 109 km3 21 Features Edit Layers of the pelagic zone Each region of the seabed has typical features such as common sediment composition typical topography salinity of water layers above it marine life magnetic direction of rocks and sedimentation Some features of the seabed include flat abyssal plains mid ocean ridges deep trenches and hydrothermal vents Seabed topography is flat where layers of sediments cover the tectonic features For example the abyssal plain regions of the ocean are relatively flat and covered in many layers of sediments 22 Sediments in these flat areas come from various sources including but not limited to land erosion sediments from rivers chemically precipitated sediments from hydrothermal vents Microorganism activity sea currents eroding the seabed and transporting sediments to the deeper ocean and phytoplankton shell materials Where the seafloor is actively spreading and sedimentation is relatively light such as in the northern and eastern Atlantic Ocean the original tectonic activity can be clearly seen as straight line cracks or vents thousands of kilometers long These underwater mountain ranges are known as mid ocean ridges 7 Other seabed environments include hydrothermal vents cold seeps and shallow areas Marine life is abundant in the deep sea around hydrothermal vents 23 Large deep sea communities of marine life have been discovered around black and white smokers vents emitting chemicals toxic to humans and most vertebrates This marine life receives its energy both from the extreme temperature difference typically a drop of 150 degrees and from chemosynthesis by bacteria Brine pools are another seabed feature 24 usually connected to cold seeps In shallow areas the seabed can host sediments created by marine life such as corals fish algae crabs marine plants and other organisms Human impact EditExploration Edit Main articles Deep sea exploration and Oceanography History source source source source source source source source source source source source source source A video describing the operation and use of an autonomous lander in deep sea research The seabed has been explored by submersibles such as Alvin and to some extent scuba divers with special equipment Hydrothermal vents were discovered by an underwater camera platform by researchers in 1977 23 In recent years satellite measurements of ocean surface topography show very clear maps of the seabed 25 and these satellite derived maps are used extensively in the study and exploration of the ocean floor Plastic pollution Edit In 2020 scientists created what may be the first scientific estimate of how much microplastic currently resides in Earth s seafloor after investigating six areas of 3 km depth 300 km off the Australian coast They found the highly variable microplastic counts to be proportionate to plastic on the surface and the angle of the seafloor slope By averaging the microplastic mass per cm3 they estimated that Earth s seafloor contains 14 million tons of microplastic about double the amount they estimated based on data from earlier studies despite calling both estimates conservative as coastal areas are known to contain much more microplastic pollution These estimates are about one to two times the amount of plastic thought per Jambeck et al 2015 to currently enter the oceans annually 26 27 28 Exploitation Edit This section is an excerpt from Deep sea mining edit Schematic of a polymetallic nodule mining operation From top to bottom the three zoom in panels illustrate the surface operation vessel the midwater sediment plume and the nodule collector operating on the seabed The midwater plume comprises two stages i the dynamic plume in which the sediment laden discharge water rapidly descends and dilutes to a neutral buoyancy depth and ii the subsequent ambient plume that is advected by the ocean current and subject to background turbulence and settling MIT 2021 Deep sea mining is a growing subfield of experimental seabed mining that involves the retrieval of minerals and deposits from the ocean floor found at depths of 200 metres 660 ft or greater 29 30 As of 2021 the majority of marine mining efforts are limited to shallow coastal waters only where sand tin and diamonds are more readily accessible 31 There are three types of deep sea mining that have generated great interest polymetallic nodule mining polymetallic sulphide mining and the mining of cobalt rich ferromanganese crusts 32 The majority of proposed deep sea mining sites are near of polymetallic nodules or active and extinct hydrothermal vents at 1 400 to 3 700 metres 4 600 to 12 100 ft below the ocean s surface 33 The vents create globular or massive sulfide deposits which contain valuable metals such as silver gold copper manganese cobalt and zinc 34 35 The deposits are mined using either hydraulic pumps or bucket systems that take ore to the surface to be processed Marine minerals include sea dredged and seabed minerals Sea dredged minerals are normally extracted by dredging operations within coastal zones to maximum sea depths of about 200 m Minerals normally extracted from these depths include sand silt and mud for construction purposes mineral rich sands such as ilmenite and diamonds 36 As with all mining operations deep sea mining raises questions about its environmental impact There is a growing debate about whether deep sea mining should be allowed 37 Environmental advocacy groups such as Greenpeace and the Deep Sea Mining Campaign 38 have argued that seabed mining should not be permitted in most of the world s oceans because of the potential for damage to deep sea ecosystems and pollution by heavy metal laden plumes 34 Prominent environmental activists and state leaders have also called for moratoriums or total bans due to the potential of devastating environmental impacts 39 40 Some argue that there should be a total ban on seabed mining 41 Some anti seabed mining campaigns have won the support of large industry such as some of the technology giants and large car companies However these same companies will be increasingly reliant on the metals seabed minerals can provide Some scientists argue that seabed mining should not go ahead as we know such a relatively small amount about the biodiversity of the deep ocean environment 42 Individual countries which with significant deposits of seabed minerals within their large EEZ s are making their own decisions pertaining to seabed mining exploring ways of undertaking seabed mining without causing too much damage to the deep ocean environment 43 or deciding not to develop seabed mines 44 Some companies are attempting to build polymetallic deep sea mining equipment which does no serious harm and preservers the marine habitat 45 As of 2022 there was no commercial mining of seabed minerals However the International Seabed Authority has granted 19 exploration licenses for polymetallic nodules within the Clarion Clipperton Zone 46 47 The Cook Islands Seabed Minerals Authority SBMA has granted 3 exploration licenses for polymetallic nodules within their EEZ 48 There is the potential for mining at a range of scales within the oceans from small to very large Technologies involved in the mining of seabed minerals would be highly technological and involve a range of robotic mining machines as well as surface ships and metal refineries at onshore locations One vision for the post fossil fuel world will rely on wind farms solar energy electric cars and improved battery technologies these use a high volume and wide range of metallic commodities including green or critical metals many of which are in relatively short supply Seabed mining could provide a near term solution to the provision of many of these metals though only serves to worsen the fundamental problems posed by extraction 49 50 In art and culture Edit Some children s play songs include elements such as There s a hole at the bottom of the sea or A sailor went to sea but all that he could see was the bottom of the deep blue sea On and under the seabed are archaeological sites of historic interest such as shipwrecks and sunken towns This underwater cultural heritage is protected by the UNESCO Convention on the Protection of the Underwater Cultural Heritage The convention aims at preventing looting and the destruction or loss of historic and cultural information by providing an international legal framework 51 See also EditBottom trawling Fishing method for fishing trawlers Demersal fish Fish that live and feed on or near the bottom of seas or lakes Human outpost Human habitats located in environments inhospitable for humans International waters Water outside of national jurisdiction Manganese nodule Mineral concretion on the sea bottom made of concentric layers of iron manganese hydroxides Methane clathrate Methane water lattice compound Nepheloid layer New Zealand foreshore and seabed controversy Indigenous rights controversy Offshore geotechnical engineering Sub field of engineering concerned with human made structures in the sea Petrological Database of the Ocean Floor PetBD Plate tectonics Movement of Earth s lithosphere Research vessel Ship or boat designed modified or equipped to carry out research at sea Seabed characterization Seafloor mapping Seafloor massive sulfide deposits Mineral deposits from seafloor hydrothermal vents Sediment Profile Imagery SPI Technique for photographing the interface between the seabed and the overlying waterReferences Edit Kump Lee R Kasting James F Crane Robert G 2010 Chapter 7 Circulation of the Solid Earth The Earth System 3rd ed New Jersey Pearson Education Inc pp 122 148 ISBN 978 0 321 59779 3 Open Ocean Oceans Coasts and Seashores National Park Service U S Department of the Interior Retrieved 13 October 2021 NOAA Ocean floor features National Oceanic and Atmospheric Administration Retrieved 13 October 2021 Flood Roger D Piper D J W 1997 Preface Depth Below Seafloor Conventions In Flood Piper Klaus A Peterson L C eds Proceedings of the Ocean Drilling Program Scientific Results Vol 155 p 3 doi 10 2973 odp proc sr 155 200 1997 we follow Ocean Drilling Program ODP meters below seafloor mbsf convention Parkes R John Henrik Sass 2007 Sulphate reducing bacteria environmental and engineered systems Edited by Larry L Barton University of New Mexico Sulphate reducing bacteria environmental and engineered systems Cambridge University Press pp 329 358 doi 10 1017 CBO9780511541490 012 ISBN 978 0 521 85485 6 Retrieved 11 June 2010 metres below the seafloor mbsf Murray Richard W Ocean Floor Sediments Water Encyclopedia a b Chester Roy Jickells Tim 2012 Chapter 15 The components of marine sediments Marine Geochemistry 3rd ed Blackwell Publishing Ltd pp 321 351 ISBN 978 1 4051 8734 3 Chester Roy Jickells Tim 2012 Chapter 13 Marine sediments Marine Geochemistry 3rd ed Blackwell Publishing Ltd pp 273 289 ISBN 978 1 4051 8734 3 a b c d The Bottom of the Ocean Marine Science Types of Marine Sediments Article Myriad Grobe Hannes Kiekmann Bernhard Hillenbrand Claus Dieter The memory of polar oceans PDF 37 45 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Tripati Aradhna Lab 6 Marine Sediments Marine Sediments Reading E amp SSCI15 1 UCLA 2012 a b Benthos from the Census of Antarctic Marine Life website US Department of Commerce National Oceanic and Atmospheric Administration How does pressure change with ocean depth oceanservice NOAA gov Haeckel E 1891 Plankton Studien Jenaische Zeitschrift fur Naturwissenschaft 25 Neue Folge 18 232 336 BHL ben8os Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project North American Benthological Society website Archived from the original on 2008 07 05 Retrieved 2008 08 16 Nehring S amp Albrecht U 1997 Benthos und das redundant Benton Neologismen in der deutschsprachigen Limnologie Lauterbornia 31 17 30 1 Giovanni Coco Z Zhou B van Maanen M Olabarrieta R Tinoco I Townend Morphodynamics of tidal networks Advances and challenges Marine Geology Journal 1 December 2013 Sandwell D T Smith W H F 2006 07 07 Exploring the Ocean Basins with Satellite Altimeter Data NOAA NGDC Retrieved 2007 04 21 Charette Matthew A Smith Walter H F June 2010 The Volume of Earth s Ocean Oceanography 23 2 112 114 doi 10 5670 oceanog 2010 51 Braathen Alvar Brekke Harald 7 January 2020 Chapter 1 Characterizing the Seabed a Geoscience Perspective Brill Brill Nijhoff pp 21 35 doi 10 1163 9789004391567 003 ISBN 9789004391567 S2CID 210979539 Retrieved 13 October 2021 a b The Discovery of Hydrothermal Vents Woods Hole Oceanographic Institution 11 June 2018 Retrieved 13 October 2021 Wefer Gerold Billet David Hebbeln Dierk Jorgensen Bo Barker Schluter Michael Weering Tjeerd C E Van 2013 11 11 Ocean Margin Systems Springer Science amp Business Media ISBN 978 3 662 05127 6 Ocean Surface Topography Science Mission Directorate 31 March 2010 Retrieved 13 October 2021 May Tiffany 7 October 2020 Hidden Beneath the Ocean s Surface Nearly 16 Million Tons of Microplastic The New York Times Retrieved 30 November 2020 14 million tonnes of microplastics on sea floor Australian study phys org Retrieved 9 November 2020 Barrett Justine Chase Zanna Zhang Jing Holl Mark M Banaszak Willis Kathryn Williams Alan Hardesty Britta D Wilcox Chris 2020 Microplastic Pollution in Deep Sea Sediments From the Great Australian Bight Frontiers in Marine Science 7 doi 10 3389 fmars 2020 576170 ISSN 2296 7745 S2CID 222125532 Available under CC BY 4 0 Seabed Mining The Ocean Foundation 2010 08 07 Retrieved 2021 04 02 SPC EU Deep Sea Minerals Project Publications and Reports dsm gsd spc int Retrieved 2021 09 06 Seabed Mining The Ocean Foundation 2010 08 07 Retrieved 2021 09 06 Exploration Contracts International Seabed Authority www isa org jm Retrieved 2021 04 02 Ahnert A Borowski C 2000 Environmental risk assessment of anthropogenic activity in the deep sea Journal of Aquatic Ecosystem Stress and Recovery 7 4 299 315 doi 10 1023 A 1009963912171 S2CID 82100930 a b Halfar J Fujita R M 2007 ECOLOGY Danger of Deep Sea Mining Science 316 5827 987 doi 10 1126 science 1138289 PMID 17510349 S2CID 128645876 Glasby G P 2000 ECONOMIC GEOLOGY Lessons Learned from Deep Sea Mining Science 289 5479 551 3 doi 10 1126 science 289 5479 551 PMID 17832066 S2CID 129268215 John J Gurney Alfred A Levinson and H Stuart Smith 1991 Marine mining of diamonds off the West Coast of Southern Africa Gems amp Gemology p 206 Kim Rakhyun E 2017 08 01 Should deep seabed mining be allowed Marine Policy 82 134 137 doi 10 1016 j marpol 2017 05 010 ISSN 0308 597X Rosenbaum Dr Helen November 2011 Out of Our Depth Mining the Ocean Floor in Papua New Guinea Deep Sea Mining Campaign MiningWatch Canada CELCoR Packard Foundation Retrieved 2 May 2020 Collapse of PNG deep sea mining venture sparks calls for moratorium the Guardian 2019 09 15 Retrieved 2021 04 02 David Attenborough calls for ban on devastating deep sea mining the Guardian 2020 03 12 Retrieved 2021 09 06 Google BMW Volvo and Samsung SDI sign up to WWF call for temporary ban on deep sea mining Reuters 2021 03 31 Retrieved 2021 09 06 Costa Corrado Fanelli Emanuela Marini Simone Danovaro Roberto Aguzzi Jacopo 2020 Global Deep Sea Biodiversity Research Trends Highlighted by Science Mapping Approach Frontiers in Marine Science 7 384 doi 10 3389 fmars 2020 00384 ISSN 2296 7745 SPC EU Deep Sea Minerals Project Home dsm gsd spc int Retrieved 2021 09 06 The Environmental Protection Authority EPA has refused an application by Chatham Rock Phosphate Limited CRP Deepwater group 2015 Archived from the original on 2016 01 24 Retrieved 6 September 2021 Impossible Mining Archived from the original on 2022 06 08 Retrieved 2022 06 13 Exploration Contracts International Seabed Authority isa org jm Retrieved 2021 09 06 Deeperminers site name Retrieved 2023 01 19 Cook Islands Seabed Minerals Authority Map SPC 2013 Deep Sea Minerals Deep Sea Minerals and the Green Economy Archived 2021 11 04 at the Wayback Machine Baker E and Beaudoin Y Eds Vol 2 Secretariat of the Pacific Community https seas at risk org wp content uploads 2021 06 Breaking Free From Mining pdf Archived 2021 12 23 at the Wayback Machine Safeguarding the Underwater Cultural Heritage UNESCO Retrieved 12 September 2012 Further reading EditRoger Hekinian Sea Floor Exploration Scientific Adventures Diving into the Abyss Springer 2014 ISBN 978 3 319 03202 3 print ISBN 978 3 319 03203 0 eBook Stephane Sainson Electromagnetic Seabed Logging A new tool for geoscientists Springer 2016 ISBN 978 3 319 45353 8 print ISBN 978 3 319 45355 2 eBook External links Edit Look up seabed in Wiktionary the free dictionary Understanding the Seafloor presentation from Cosee the Center for Ocean Sciences Educational Excellence Ocean Explorer www oceanexplorer noaa gov Public outreach site for explorations sponsored by the Office of Ocean Exploration NOAA Ocean Explorer Gallery Submarine Ring of Fire 2006 Gallery Submarine Ring of Fire 2004 Gallery A rich collection of images video audio and podcast NOAA Ocean Explorer YouTube Channel Submarine Ring of Fire Mariana Arc Explore the volcanoes of the Mariana Arc Submarine Ring of Fire Age of the Ocean Floor National Geophysical Data Center Astonishing deep sea life on TED conference Retrieved from https en wikipedia org w index php title Seabed amp oldid 1133985162, wikipedia, wiki, book, books, library,

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