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Earth's ocean
Pacific Ocean of Earth seen from space in 1969
Basin countriesList of countries by length of coastline
Surface area361,000,000 km2 (139,382,879 sq mi)
(71% Earth's surface area)[1]
Average depth3.688 km (2 mi)[2]
Max. depth11.034 km (6.856 mi)
(Challenger Deep)[3]
Water volume1,370,000,000 km3 (328,680,479 cu mi)[1] (97.5% of Earth's water)
Shore length1Low interval calculation: 356,000 km (221,208 mi)[4] High interval calculation: 1,634,701 km (1,015,756 mi)[5][vague]
Max. temperature
  • 30 °C (86 °F) (max. surface)
  • 20 °C (68 °F) (avg. surface)
  • 4 °C (39 °F) (avg. overall)[6][7]
Min. temperature
  • −2 °C (28 °F) (surface)
  • 1 °C (34 °F) (deepest points)[6][7]
Sections/sub-basinsMain divisions (volume %): Other divisions: Marginal seas
TrenchesList of oceanic trenches
1 Shore length is not a well-defined measure.

The ocean is the body of salt water that covers approximately 70.8% of Earth.[8] In English, the term ocean also refers to any of the large bodies of water into which the world ocean is conventionally divided.[9] The following names describe five different areas of the ocean: Pacific, Atlantic, Indian, Antarctic/Southern, and Arctic.[10][11] The ocean contains 97% of Earth's water[8] and is the primary component of Earth's hydrosphere and is thereby essential to life on Earth. The ocean influences climate and weather patterns, the carbon cycle, and the water cycle by acting as a huge heat reservoir.

Ocean scientists split the ocean into vertical and horizontal zones based on physical and biological conditions. The pelagic zone is the open ocean's water column from the surface to the ocean floor. The water column is further divided into zones based on depth and the amount of light present. The photic zone starts at the surface and is defined to be "the depth at which light intensity is only 1% of the surface value"[12]: 36  (approximately 200 m in the open ocean). This is the zone where photosynthesis can occur. In this process plants and microscopic algae (free floating phytoplankton) use light, water, carbon dioxide, and nutrients to produce organic matter. As a result, the photic zone is the most biodiverse and the source of the food supply which sustains most of the ocean ecosystem. Ocean photosynthesis also produces half of the oxygen in the Earth's atmosphere.[13] Light can only penetrate a few hundred more meters; the rest of the deeper ocean is cold and dark (these zones are called mesopelagic and aphotic zones). The continental shelf is where the ocean meets dry land. It is more shallow, with a depth of a few hundred meters or less. Human activity often has negative impacts on marine life within the continental shelf.

Ocean temperatures depend on the amount of solar radiation reaching the ocean surface. In the tropics, surface temperatures can rise to over 30 °C (86 °F). Near the poles where sea ice forms, the temperature in equilibrium is about −2 °C (28 °F). In all parts of the ocean, deep ocean temperatures range between −2 °C (28 °F) and 5 °C (41 °F).[14] Constant circulation of water in the ocean creates ocean currents. Those currents are caused by forces operating on the water, such as temperature and salinity differences, atmospheric circulation (wind), and the Coriolis effect.[15] Tides create tidal currents, while wind and waves cause surface currents. The Gulf Stream, Kuroshio Current, Agulhas Current and Antarctic Circumpolar Current are all major ocean currents. Such currents transport massive amounts of water, gases, pollutants and heat to different parts of the world, and from the surface into the deep ocean. All this has impacts on the global climate system.

Ocean water contains dissolved gases, including oxygen, carbon dioxide and nitrogen. An exchange of these gases occurs at the ocean's surface. The solubility of these gases depends on the temperature and salinity of the water.[16] The carbon dioxide concentration in the atmosphere is rising due to CO2 emissions, mainly from fossil fuel combustion. As the oceans absorb CO2 from the atmosphere, a higher concentration leads to ocean acidification (a drop in pH value).[17]

The ocean provides many benefits to humans such as ecosystem services, access to seafood and other marine resources, and a means of transport. The ocean is known to be the habitat of over 230,000 species, but may hold considerably more – perhaps over two million species.[18] Yet, the ocean faces many environmental threats, such as marine pollution, overfishing, and the effects of climate change. Those effects include ocean warming, ocean acidification and sea level rise. The continental shelf and coastal waters are most affected by human activity.

Terminology

Ocean and sea

The terms "the ocean" or "the sea" used without specification refer to the interconnected body of salt water covering the majority of Earth's surface.[10][11] It includes the Pacific, Atlantic, Indian, Southern/Antarctic, and Arctic oceans.[19] As a general term, "the ocean" and "the sea" are often interchangeable.[20]

Strictly speaking, a "sea" is a body of water (generally a division of the world ocean) partly or fully enclosed by land.[21] The word "sea" can also be used for many specific, much smaller bodies of seawater, such as the North Sea or the Red Sea. There is no sharp distinction between seas and oceans, though generally seas are smaller, and are often partly (as marginal seas) or wholly (as inland seas) bordered by land.[22]

World Ocean

The contemporary concept of the World Ocean was coined in the early 20th century by the Russian oceanographer Yuly Shokalsky to refer to the continuous ocean that covers and encircles most of Earth.[23][24] The global, interconnected body of salt water is sometimes referred to as the World Ocean, global ocean or the great ocean.[25][26][27] The concept of a continuous body of water with relatively unrestricted exchange between its components is critical in oceanography.[28]

Etymology

The word ocean comes from the figure in classical antiquity, Oceanus (/ˈsənəs/; ‹See Tfd›Greek: Ὠκεανός Ōkeanós,[29] pronounced [ɔːkeanós]), the elder of the Titans in classical Greek mythology. Oceanus was believed by the ancient Greeks and Romans to be the divine personification of an enormous river encircling the world.

The concept of Ōkeanós has an Indo-European connection. Greek Ōkeanós has been compared to the Vedic epithet ā-śáyāna-, predicated of the dragon Vṛtra-, who captured the cows/rivers. Related to this notion, the Okeanos is represented with a dragon-tail on some early Greek vases.[30]

Natural history

Origin of water

Scientists believe that a sizable quantity of water would have been in the material that formed Earth.[31] Water molecules would have escaped Earth's gravity more easily when it was less massive during its formation. This is called atmospheric escape.

During planetary formation, Earth possibly had magma oceans. Subsequently, outgassing, volcanic activity and meteorite impacts, produced an early atmosphere of carbon dioxide, nitrogen and water vapor, according to current theories. The gases and the atmosphere are thought to have accumulated over millions of years. After Earth's surface had significantly cooled, the water vapor over time would have condensed, forming Earth's first oceans.[32] The early oceans might have been significantly hotter than today and appeared green due to high iron content.[33]

Geological evidence helps constrain the time frame for liquid water existing on Earth. A sample of pillow basalt (a type of rock formed during an underwater eruption) was recovered from the Isua Greenstone Belt and provides evidence that water existed on Earth 3.8 billion years ago.[34] In the Nuvvuagittuq Greenstone Belt, Quebec, Canada, rocks dated at 3.8 billion years old by one study[35] and 4.28 billion years old by another[36] show evidence of the presence of water at these ages.[34] If oceans existed earlier than this, any geological evidence either has yet to be discovered, or has since been destroyed by geological processes like crustal recycling. However, in August 2020, researchers reported that sufficient water to fill the oceans may have always been on the Earth since the beginning of the planet's formation.[37][38][39] In this model, atmospheric greenhouse gases kept the oceans from freezing when the newly forming Sun had only 70% of its current luminosity.[40]

Ocean formation

The origin of Earth's oceans is unknown. Oceans are thought to have formed in the Hadean eon and may have been the cause for the emergence of life.

Plate tectonics, post-glacial rebound, and sea level rise continually change the coastline and structure of the world ocean. A global ocean has existed in one form or another on Earth for eons.

Since its formation the ocean has taken many conditions and shapes with many past ocean divisions and potentially at times covering the whole globe.[41]

During colder climatic periods, more ice caps and glaciers form, and enough of the global water supply accumulates as ice to lessen the amounts in other parts of the water cycle. The reverse is true during warm periods. During the last ice age, glaciers covered almost one-third of Earth's land mass with the result being that the oceans were about 122 m (400 ft) lower than today. During the last global "warm spell," about 125,000 years ago, the seas were about 5.5 m (18 ft) higher than they are now. About three million years ago the oceans could have been up to 50 m (165 ft) higher.[42]

Geography

World map of the five-ocean model with approximate boundaries

The entire ocean, containing 97% of Earth's water, spans 70.8% of Earth's surface,[8] making it Earth's global ocean or world ocean.[23][25] This makes Earth, along with its vibrant hydrosphere a "water world"[43][44] or "ocean world",[45][46] particularly in Earth's early history when the ocean is thought to have possibly covered Earth completely.[41] The ocean's shape is irregular, unevenly dominating the Earth's surface. This leads to the distinction of the Earth's surface into a water and land hemisphere, as well as the division of the ocean into different oceans.

Seawater covers about 361,000,000 km2 (139,000,000 sq mi) and the ocean's furthest pole of inaccessibility, known as "Point Nemo", in a region known as spacecraft cemetery of the South Pacific Ocean, at 48°52.6′S 123°23.6′W / 48.8767°S 123.3933°W / -48.8767; -123.3933 (Point Nemo). This point is roughly 2,688 km (1,670 mi) from the nearest land.[47]

Oceanic divisions

Map of Earth centered on its ocean, showing the different ocean divisions

There are different customs to subdivide the ocean and are adjourned by smaller bodies of water such as, seas, gulfs, bays, bights, and straits.

The ocean is customarily divided into five principal oceans – listed below in descending order of area and volume:

Oceans by size
# Ocean Location Area
(km2)
Volume
(km3)
Avg. depth
(m)
Coastline
(km)[48]
1 Pacific Ocean Between Asia and Australasia and the Americas[49] 168,723,000
(46.6%)
669,880,000
(50.1%)
3,970 135,663
(35.9%)
2 Atlantic Ocean Between the Americas and Europe and Africa[50] 85,133,000
(23.5%)
310,410,900
(23.3%)
3,646 111,866
(29.6%)
3 Indian Ocean Between southern Asia, Africa and Australia[51] 70,560,000
(19.5%)
264,000,000
(19.8%)
3,741 66,526
(17.6%)
4 Antarctic/Southern Ocean Between Antarctica and the Pacific, Atlantic and Indian oceans
Sometimes considered an extension of those three oceans.[52][53]
21,960,000
(6.1%)
71,800,000
(5.4%)
3,270 17,968
(4.8%)
5 Arctic Ocean Between northern North America and Eurasia in the Arctic
Sometimes considered a marginal sea of the Atlantic.[54][55][56]
15,558,000
(4.3%)
18,750,000
(1.4%)
1,205 45,389
(12.0%)
Total 361,900,000
(100%)
1.335×10^9
(100%)
3,688 377,412
(100%)
NB: Volume, area, and average depth figures include NOAA ETOPO1 figures for marginal South China Sea.
Sources: Encyclopedia of Earth,[49][50][51][52][56] International Hydrographic Organization,[53] Regional Oceanography: an Introduction (Tomczak, 2005),[54] Encyclopædia Britannica,[55] and the International Telecommunication Union.[48]

Ocean basins

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)

The ocean fills Earth's oceanic basins. Earth's oceanic basins cover different geologic provinces of Earth's oceanic crust as well as continental crust. As such it covers mainly Earth's structural basins, but also continental shelfs.

In mid-ocean, magma is constantly being thrust through the seabed between adjoining plates to form mid-oceanic ridges and here convection currents within the mantle tend to drive the two plates apart. Parallel to these ridges and nearer the coasts, one oceanic plate may slide beneath another oceanic plate in a process known as subduction. Deep trenches are formed here and the process is accompanied by friction as the plates grind together. The movement proceeds in jerks which cause earthquakes, heat is produced and magma is forced up creating underwater mountains, some of which may form chains of volcanic islands near to deep trenches. Near some of the boundaries between the land and sea, the slightly denser oceanic plates slide beneath the continental plates and more subduction trenches are formed. As they grate together, the continental plates are deformed and buckle causing mountain building and seismic activity.[57][58]

Every ocean basin has a mid-ocean ridge, which creates a long mountain range beneath the ocean. Together they form the global mid-oceanic ridge system that features the longest mountain range in the world. The longest continuous mountain range is 65,000 km (40,000 mi). This underwater mountain range is several times longer than the longest continental mountain range – the Andes.[59]

Oceanographers state that less than 20% of the oceans have been mapped.[60][vague]

Interaction with the coast

Lighthouse at the coast of Ocean County, New Jersey, U.S., facing the Atlantic Ocean at sunrise

The zone where land meets sea is known as the coast, and the part between the lowest spring tides and the upper limit reached by splashing waves is the shore. A beach is the accumulation of sand or shingle on the shore.[61] A headland is a point of land jutting out into the sea and a larger promontory is known as a cape. The indentation of a coastline, especially between two headlands, is a bay, a small bay with a narrow inlet is a cove and a large bay may be referred to as a gulf.[62] Coastlines are influenced by several factors including the strength of the waves arriving on the shore, the gradient of the land margin, the composition and hardness of the coastal rock, the inclination of the off-shore slope and the changes of the level of the land due to local uplift or submergence.[61]

Normally, waves roll towards the shore at the rate of six to eight per minute and these are known as constructive waves as they tend to move material up the beach and have little erosive effect. Storm waves arrive on shore in rapid succession and are known as destructive waves as the swash moves beach material seawards. Under their influence, the sand and shingle on the beach is ground together and abraded. Around high tide, the power of a storm wave impacting on the foot of a cliff has a shattering effect as air in cracks and crevices is compressed and then expands rapidly with release of pressure. At the same time, sand and pebbles have an erosive effect as they are thrown against the rocks. This tends to undercut the cliff, and normal weathering processes such as the action of frost follows, causing further destruction. Gradually, a wave-cut platform develops at the foot of the cliff and this has a protective effect, reducing further wave-erosion.[61]

Material worn from the margins of the land eventually ends up in the sea. Here it is subject to attrition as currents flowing parallel to the coast scour out channels and transport sand and pebbles away from their place of origin. Sediment carried to the sea by rivers settles on the seabed causing deltas to form in estuaries. All these materials move back and forth under the influence of waves, tides and currents.[61] Dredging removes material and deepens channels but may have unexpected effects elsewhere on the coastline. Governments make efforts to prevent flooding of the land by the building of breakwaters, seawalls, dykes and levees and other sea defences. For instance, the Thames Barrier is designed to protect London from a storm surge,[63] while the failure of the dykes and levees around New Orleans during Hurricane Katrina created a humanitarian crisis in the United States.

Physical properties

Color

Ocean chlorophyll concentration is a proxy for phytoplankton biomass. In this map, blue colors represent lower chlorophyll and reds represent higher chlorophyll. Satellite-measured chlorophyll is estimated based on ocean color by how green the color of the water appears from space.

Most of the ocean is blue in color, but in some places the ocean is blue-green, green, or even yellow to brown.[64] Blue ocean color is a result of several factors. First, water preferentially absorbs red light, which means that blue light remains and is reflected back out of the water. Red light is most easily absorbed and thus does not reach great depths, usually to less than 50 meters (164 ft). Blue light, in comparison, can penetrate up to 200 meters (656 ft).[65] Second, water molecules and very tiny particles in ocean water preferentially scatter blue light more than light of other colors. Blue light scattering by water and tiny particles happens even in the very clearest ocean water,[66] and is similar to blue light scattering in the sky.

The main substances that affect the color of the ocean include dissolved organic matter, living phytoplankton with chlorophyll pigments, and non-living particles like marine snow and mineral sediments.[67] Chlorophyll can be measured by satellite observations and serves as a proxy for ocean productivity (marine primary productivity) in surface waters. In long term composite satellite images, regions with high ocean productivity show up in yellow and green colors because they contain more (green) phytoplankton, whereas areas of low productivity show up in blue.

Water cycle, weather, and rainfall

The ocean is a major driver of Earth's water cycle.

Ocean water represents the largest body of water within the global water cycle (oceans contain 97% of Earth's water). Evaporation from the ocean moves water into the atmosphere to later rain back down onto land and the ocean.[68] Oceans have a significant effect on the biosphere. The ocean as a whole is thought to cover approximately 90% of the Earth's biosphere.[60] Oceanic evaporation, as a phase of the water cycle, is the source of most rainfall (about 90%),[68] causing a global cloud cover of 67% and a consistent oceanic cloud cover of 72%.[69] Ocean temperatures affect climate and wind patterns that affect life on land. One of the most dramatic forms of weather occurs over the oceans: tropical cyclones (also called "typhoons" and "hurricanes" depending upon where the system forms).

As the world's ocean is the principal component of Earth's hydrosphere, it is integral to life on Earth, forms part of the carbon cycle and water cycle, and – as a huge heat reservoir – influences climate and weather patterns.

Waves and swell

Movement of water as waves pass

The motions of the ocean surface, known as undulations or wind waves, are the partial and alternate rising and falling of the ocean surface. The series of mechanical waves that propagate along the interface between water and air is called swell – a term used in sailing, surfing and navigation.[70] These motions profoundly affect ships on the surface of the ocean and the well-being of people on those ships who might suffer from sea sickness.

Wind blowing over the surface of a body of water forms waves that are perpendicular to the direction of the wind. The friction between air and water caused by a gentle breeze on a pond causes ripples to form. A stronger gust blowing over the ocean causes larger waves as the moving air pushes against the raised ridges of water. The waves reach their maximum height when the rate at which they are travelling nearly matches the speed of the wind. In open water, when the wind blows continuously as happens in the Southern Hemisphere in the Roaring Forties, long, organized masses of water called swell roll across the ocean.[71]: 83–84 [72][73] If the wind dies down, the wave formation is reduced, but already-formed waves continue to travel in their original direction until they meet land. The size of the waves depends on the fetch, the distance that the wind has blown over the water and the strength and duration of that wind. When waves meet others coming from different directions, interference between the two can produce broken, irregular seas.[72]

Constructive interference can lead to the formation of unusually high rogue waves.[74] Most waves are less than 3 m (10 ft) high[74] and it is not unusual for strong storms to double or triple that height.[75] Rogue waves, however, have been documented at heights above 25 meters (82 ft).[76][77]

The top of a wave is known as the crest, the lowest point between waves is the trough and the distance between the crests is the wavelength. The wave is pushed across the surface of the ocean by the wind, but this represents a transfer of energy and not horizontal movement of water. As waves approach land and move into shallow water, they change their behavior. If approaching at an angle, waves may bend (refraction) or wrap around rocks and headlands (diffraction). When the wave reaches a point where its deepest oscillations of the water contact the ocean floor, they begin to slow down. This pulls the crests closer together and increases the waves' height, which is called wave shoaling. When the ratio of the wave's height to the water depth increases above a certain limit, it "breaks", toppling over in a mass of foaming water.[74] This rushes in a sheet up the beach before retreating into the ocean under the influence of gravity.[78]

Earthquakes, volcanic eruptions or other major geological disturbances can set off waves that can lead to tsunamis in coastal areas which can be very dangerous.[79][80]

Sea level and surface

The ocean's surface is an important reference point for oceanography and geography, particularly as mean sea level. The ocean surface has globally little, but measurable topography, depending on the ocean's volumes.

The ocean surface is a crucial interface for oceanic and atmospheric processes. Allowing interchange of particles, enriching the air and water, as well as grounds by some particles becoming sediments. This interchange has fertilized life in the ocean, on land and air. All these processes and components together make up ocean surface ecosystems.

Tides

High tide and low tide in the Bay of Fundy, Canada

Tides are the regular rise and fall in water level experienced by oceans, primarily driven by the Moon's gravitational tidal forces upon the Earth. Tidal forces affect all matter on Earth, but only fluids like the ocean demonstrate the effects on human timescales. (For example, tidal forces acting on rock may produce tidal locking between two planetary bodies.) Though primarily driven by the Moon's gravity, oceanic tides are also substantially modulated by the Sun's tidal forces, by the rotation of the Earth, and by the shape of the rocky continents blocking oceanic water flow. (Tidal forces vary more with distance than the "base" force of gravity: the Moon's tidal forces on Earth are more than double the Sun's,[81] despite the latter's much stronger gravitational force on Earth. Earth's tidal forces upon the Moon are 20x stronger than the Moon's tidal forces on the Earth.)

The primary effect of lunar tidal forces is to bulge Earth matter towards the near and far sides of the Earth, relative to the moon. The "perpendicular" sides, from which the Moon appears in line with the local horizon, experience "tidal troughs". Since it takes nearly 25 hours for the Earth to rotate under the Moon (accounting for the Moon's 28 day orbit around Earth), tides thus cycle over a course of 12.5 hours. However, the rocky continents pose obstacles for the tidal bulges, so the timing of tidal maxima may not actually align with the Moon in most localities on Earth, as the oceans are forced to "dodge" the continents. Timing and magnitude of tides vary widely across the Earth as a result of the continents. Thus, knowing the Moon's position does not allow a local to predict tide timings, instead requiring precomputed tide tables which account for the continents and the Sun, among others.

During each tidal cycle, at any given place the tidal waters rise to maximum height, high tide, before ebbing away again to the minimum level, low tide. As the water recedes, it gradually reveals the foreshore, also known as the intertidal zone. The difference in height between the high tide and low tide is known as the tidal range or tidal amplitude.[82][83] When the sun and moon are aligned (full moon or new moon), the combined effect results in the higher "spring tides", while the sun and moon misaligning (half moons) result in lesser tidal ranges.[82]

In the open ocean tidal ranges are less than 1 meter, but in coastal areas these tidal ranges increase to more than 10 meters in some areas.[84] Some of the largest tidal ranges in the world occur in the Bay of Fundy and Ungava Bay in Canada, reaching up to 16 meters.[85] Other locations with record high tidal ranges include the Bristol Channel between England and Wales, Cook Inlet in Alaska, and the Río Gallegos in Argentina.[86]

Tides are not to be confused with storm surges, which can occur when high winds pile water up against the coast in a shallow area and this, coupled with a low pressure system, can raise the surface of the ocean dramatically above a typical high tide.

Depth

The average depth of the oceans is about 4 km. More precisely the average depth is 3,688 meters (12,100 ft).[72] Nearly half of the world's marine waters are over 3,000 meters (9,800 ft) deep.[27] "Deep ocean," which is anything below 200 meters (660 ft), covers about 66% of Earth's surface.[87] This figure does not include seas not connected to the World Ocean, such as the Caspian Sea.

The deepest region of the ocean is at the Mariana Trench, located in the Pacific Ocean near the Northern Mariana Islands.[88] The maximum depth has been estimated to be 10,971 meters (35,994 ft). The British naval vessel Challenger II surveyed the trench in 1951 and named the deepest part of the trench the "Challenger Deep". In 1960, the Trieste successfully reached the bottom of the trench, manned by a crew of two men.

Oceanic zones

Drawing showing divisions according to depth and distance from shore
The major oceanic zones, based on depth and biophysical conditions

Oceanographers classify the ocean into vertical and horizontal zones based on physical and biological conditions. The pelagic zone consists of the water column of the open ocean, and can be divided into further regions categorized by light abundance and by depth.

Grouped by light penetration

The ocean zones can be grouped by light penetration into (from top to bottom): the photic zone, the mesopelagic zone and the aphotic deep ocean zone:

  • The photic zone is defined to be "the depth at which light intensity is only 1% of the surface value".[12]: 36  This is usually up to a depth of approximately 200 m in the open ocean. It is the region where photosynthesis can occur and is, therefore, the most biodiverse. Photosynthesis by plants and microscopic algae (free floating phytoplankton) allows the creation of organic matter from chemical precursors including water and carbon dioxide. This organic matter can then be consumed by other creatures. Much of the organic matter created in the photic zone is consumed there but some sinks into deeper waters. The pelagic part of the photic zone is known as the epipelagic.[89] The actual optics of light reflecting and penetrating at the ocean surface are complex.[12]: 34–39 
  • Below the photic zone is the mesopelagic or twilight zone where there is a very small amount of light. The basic concept is that with that little light photosynthesis is unlikely to achieve any net growth over respiration.[12]: 116–124 
  • Below that is the aphotic deep ocean to which no surface sunlight at all penetrates. Life that exists deeper than the photic zone must either rely on material sinking from above (see marine snow) or find another energy source. Hydrothermal vents are a source of energy in what is known as the aphotic zone (depths exceeding 200 m).[89]

Grouped by depth and temperature

The pelagic part of the aphotic zone can be further divided into vertical regions according to depth and temperature:[89]

  • The mesopelagic is the uppermost region. Its lowermost boundary is at a thermocline of 12 °C (54 °F) which generally lies at 700–1,000 meters (2,300–3,300 ft) in the tropics. Next is the bathypelagic lying between 10 and 4 °C (50 and 39 °F), typically between 700–1,000 meters (2,300–3,300 ft) and 2,000–4,000 meters (6,600–13,100 ft). Lying along the top of the abyssal plain is the abyssopelagic, whose lower boundary lies at about 6,000 meters (20,000 ft). The last and deepest zone is the hadalpelagic which includes the oceanic trench and lies between 6,000–11,000 meters (20,000–36,000 ft).
  • The benthic zones are aphotic and correspond to the three deepest zones of the deep-sea. The bathyal zone covers the continental slope down to about 4,000 meters (13,000 ft). The abyssal zone covers the abyssal plains between 4,000 and 6,000 m. Lastly, the hadal zone corresponds to the hadalpelagic zone, which is found in oceanic trenches.

Distinct boundaries between ocean surface waters and deep waters can be drawn based on the properties of the water. These boundaries are called thermoclines (temperature), haloclines (salinity), chemoclines (chemistry), and pycnoclines (density). If a zone undergoes dramatic changes in temperature with depth, it contains a thermocline, a distinct boundary between warmer surface water and colder deep water. In tropical regions, the thermocline is typically deeper compared to higher latitudes. Unlike polar waters, where solar energy input is limited, temperature stratification is less pronounced, and a distinct thermocline is often absent. This is due to the fact that surface waters in polar latitudes are nearly as cold as deeper waters. Below the thermocline, water everywhere in the ocean is very cold, ranging from −1 °C to 3 °C. Because this deep and cold layer contains the bulk of ocean water, the average temperature of the world ocean is 3.9 °C.[90] If a zone undergoes dramatic changes in salinity with depth, it contains a halocline. If a zone undergoes a strong, vertical chemistry gradient with depth, it contains a chemocline. Temperature and salinity control ocean water density. Colder and saltier water is denser, and this density plays a crucial role in regulating the global water circulation within the ocean.[89] The halocline often coincides with the thermocline, and the combination produces a pronounced pycnocline, a boundary between less dense surface water and dense deep water.

Grouped by distance from land

The pelagic zone can be further subdivided into two sub regions based on distance from land: the neritic zone and the oceanic zone. The neritic zone covers the water directly above the continental shelves, including coastal waters. On the other hand, the oceanic zone includes all the completely open water.

The littoral zone covers the region between low and high tide and represents the transitional area between marine and terrestrial conditions. It is also known as the intertidal zone because it is the area where tide level affects the conditions of the region.[89]

Volumes

The combined volume of water in all the oceans is roughly 1.335 billion cubic kilometers (1.335 sextillion liters, 320.3 million cubic miles).[72][91][92]

It has been estimated that there are 1.386 billion cubic kilometres (333 million cubic miles) of water on Earth.[93][94][95] This includes water in gaseous, liquid and frozen forms as soil moisture, groundwater and permafrost in the Earth's crust (to a depth of 2 km); oceans and seas, lakes, rivers and streams, wetlands, glaciers, ice and snow cover on Earth's surface; vapour, droplets and crystals in the air; and part of living plants, animals and unicellular organisms of the biosphere. Saltwater accounts for 97.5% of this amount, whereas fresh water accounts for only 2.5%. Of this fresh water, 68.9% is in the form of ice and permanent snow cover in the Arctic, the Antarctic and mountain glaciers; 30.8% is in the form of fresh groundwater; and only 0.3% of the fresh water on Earth is in easily accessible lakes, reservoirs and river systems.[96]

The total mass of Earth's hydrosphere is about 1.4 × 1018 tonnes, which is about 0.023% of Earth's total mass. At any given time, about 2 × 1013 tonnes of this is in the form of water vapor in the Earth's atmosphere (for practical purposes, 1 cubic metre of water weighs 1 tonne). Approximately 71% of Earth's surface, an area of some 361 million square kilometres (139.5 million square miles), is covered by ocean. The average salinity of Earth's oceans is about 35 grams of salt per kilogram of sea water (3.5%).[97]

Temperature

Ocean temperatures depends on the amount of solar radiation falling on its surface. In the tropics, with the Sun nearly overhead, the temperature of the surface layers can rise to over 30 °C (86 °F) while near the poles the temperature in equilibrium with the sea ice is about −2 °C (28 °F). There is a continuous circulation of water in the oceans. Warm surface currents cool as they move away from the tropics, and the water becomes denser and sinks. The cold water moves back towards the equator as a deep sea current, driven by changes in the temperature and density of the water, before eventually welling up again towards the surface. Deep ocean water has a temperature between −2 °C (28 °F) and 5 °C (41 °F) in all parts of the globe.[14]

The temperature gradient over the water depth is related to the way the surface water mixes with deeper water or does not mix (a lack of mixing is called ocean stratification). This depends on the temperature: in the tropics the warm surface layer of about 100 m is quite stable and does not mix much with deeper water, while near the poles winter cooling and storms makes the surface layer denser and it mixes to great depth and then stratifies again in summer. The photic depth is typically about 100 m (but varies) and is related to this heated surface layer.[98]

It is clear that the ocean is warming as a result of climate change, and this rate of warming is increasing.[99]: 9  The global ocean was the warmest it had ever been recorded by humans in 2022.[100] This is determined by the ocean heat content, which exceeded the previous 2021 maximum in 2022.[100] The steady rise in ocean temperatures is an unavoidable result of the Earth's energy imbalance, which is primarily caused by rising levels of greenhouse gases.[100] Between pre-industrial times and the 2011–2020 decade, the ocean's surface has heated between 0.68 and 1.01 °C.[101]: 1214 

Temperature and salinity by region

The temperature and salinity of ocean waters vary significantly across different regions. This is due to differences in the local water balance (precipitation vs. evaporation) and the "sea to air" temperature gradients. These characteristics can vary widely from one ocean region to another. The table below provides an illustration of the sort of values usually encountered.

General characteristics of ocean surface waters by region[102][103][104][105][106]
Characteristic Polar regions Temperate regions Tropical regions
Precipitation vs. evaporation Precip > Evap Precip > Evap Evap > Precip
Sea surface temperature in winter −2 °C 5 to 20 °C 20 to 25 °C
Average salinity 28‰ to 32‰ 35‰ 35‰ to 37‰
Annual variation of air temperature ≤ 40 °C 10 °C < 5 °C
Annual variation of water temperature < 5 °C 10 °C < 5 °C

Sea ice

Seawater with a typical salinity of 35‰ has a freezing point of about −1.8 °C (28.8 °F).[89][107] Because sea ice is less dense than water, it floats on the ocean's surface (as does fresh water ice, which has an even lower density). Sea ice covers about 7% of the Earth's surface and about 12% of the world's oceans.[108][109][110] Sea ice usually starts to freeze at the very surface, initially as a very thin ice film. As further freezing takes place, this ice film thickens and can form ice sheets. The ice formed incorporates some sea salt, but much less than the seawater it forms from. As the ice forms with low salinity this results in saltier residual seawater. This in turn increases density and promotes vertical sinking of the water.[111]

Ocean currents and global climate

Ocean surface currents
World map with colored, directed lines showing how water moves through the oceans. Cold deep water rises and warms in the central Pacific and in the Indian, whereas warm water sinks and cools near Greenland in the North Atlantic and near Antarctica in the South Atlantic.
A map of the global thermohaline circulation; blue represents deep-water currents, whereas red represents surface currents.

Types of ocean currents

An ocean current is a continuous, directed flow of seawater caused by several forces acting upon the water. These include wind, the Coriolis effect, temperature and salinity differences.[15] Ocean currents are primarily horizontal water movements that have different origins such as tides for tidal currents, or wind and waves for surface currents.

Tidal currents are in phase with the tide, hence are quasiperiodic; associated with the influence of the moon and sun pull on the ocean water. Tidal currents may form various complex patterns in certain places, most notably around headlands.[112] Non-periodic or non-tidal currents are created by the action of winds and changes in density of water. In littoral zones, breaking waves are so intense and the depth measurement so low, that maritime currents reach often 1 to 2 knots.[113]

The wind and waves create surface currents (designated as "drift currents"). These currents can decompose in one quasi-permanent current (which varies within the hourly scale) and one movement of Stokes drift under the effect of rapid waves movement (which vary on timescales of a couple of seconds). The quasi-permanent current is accelerated by the breaking of waves, and in a lesser governing effect, by the friction of the wind on the surface.[113]

This acceleration of the current takes place in the direction of waves and dominant wind. Accordingly, when the ocean depth increases, the rotation of the earth changes the direction of currents in proportion with the increase of depth, while friction lowers their speed. At a certain ocean depth, the current changes direction and is seen inverted in the opposite direction with current speed becoming null: known as the Ekman spiral. The influence of these currents is mainly experienced at the mixed layer of the ocean surface, often from 400 to 800 meters of maximum depth. These currents can considerably change and are dependent on the yearly seasons. If the mixed layer is less thick (10 to 20 meters), the quasi-permanent current at the surface can adopt quite a different direction in relation to the direction of the wind. In this case, the water column becomes virtually homogeneous above the thermocline.[113]

The wind blowing on the ocean surface will set the water in motion. The global pattern of winds (also called atmospheric circulation) creates a global pattern of ocean currents. These are driven not only by the wind but also by the effect of the circulation of the earth (coriolis force). These major ocean currents include the Gulf Stream, Kuroshio current, Agulhas current and Antarctic Circumpolar Current. The Antarctic Circumpolar Current encircles Antarctica and influences the area's climate, connecting currents in several oceans.[113]

Relationship of currents and climate

Map of the Gulf Stream, a major ocean current that transports heat from the equator to northern latitudes and moderates the climate of Europe

Collectively, currents move enormous amounts of water and heat around the globe influencing climate. These wind driven currents are largely confined to the top hundreds of meters of the ocean. At greater depth, the thermohaline circulation drives water motion. For example, the Atlantic meridional overturning circulation (AMOC) is driven by the cooling of surface waters in the polar latitudes in the north and south, creating dense water which sinks to the bottom of the ocean. This cold and dense water moves slowly away from the poles which is why the waters in the deepest layers of the world ocean are so cold. This deep ocean water circulation is relatively slow and water at the bottom of the ocean can be isolated from the ocean surface and atmosphere for hundreds or even a few thousand years.[113] This circulation has important impacts on the global climate system and on the uptake and redistribution of pollutants and gases such as carbon dioxide, for example by moving contaminants from the surface into the deep ocean.

Ocean currents greatly affect Earth's climate by transferring heat from the tropics to the polar regions. This affects air temperature and precipitation in coastal regions and further inland. Surface heat and freshwater fluxes create global density gradients, which drive the thermohaline circulation that is a part of large-scale ocean circulation. It plays an important role in supplying heat to the polar regions, and thus in sea ice regulation.[citation needed]

Oceans moderate the climate of locations where prevailing winds blow in from the ocean. At similar latitudes, a place on Earth with more influence from the ocean will have a more moderate climate than a place with more influence from land. For example, the cities San Francisco (37.8 N) and New York (40.7 N) have different climates because San Francisco has more influence from the ocean. San Francisco, on the west coast of North America, gets winds from the west over the Pacific Ocean. New York, on the east coast of North America gets winds from the west over land, so New York has colder winters and hotter, earlier summers than San Francisco. Warmer ocean currents yield warmer climates in the long term, even at high latitudes. At similar latitudes, a place influenced by warm ocean currents will have a warmer climate overall than a place influenced by cold ocean currents.[citation needed]

Changes in the thermohaline circulation are thought to have significant impacts on Earth's energy budget. Because the thermohaline circulation determines the rate at which deep waters reach the surface, it may also significantly influence atmospheric carbon dioxide concentrations. Modern observations, climate simulations and paleoclimate reconstructions suggest that the Atlantic Meridional Overturning Circulation (AMOC) has weakened since the preindustrial era. The latest climate change projections in 2021 suggest that the AMOC is likely to weaken further over the 21st century.[114]: 19  Such a weakening could cause large changes to global climate, with the North Atlantic particularly vulnerable.[114]: 19 

Chemical properties

Salinity

Annual mean sea surface salinity in practical salinity units (psu) from the World Ocean Atlas[115]

Salinity is a measure of the total amounts of dissolved salts in seawater. It was originally measured via measurement of the amount of chloride in seawater and hence termed chlorinity. It is now standard practice to gauge it by measuring electrical conductivity of the water sample. Salinity can be calculated using the chlorinity, which is a measure of the total mass of halogen ions (includes fluorine, chlorine, bromine, and iodine) in seawater. According to an international agreement, the following formula is used to determine salinity:[116]

Salinity (in ‰) = 1.80655 × Chlorinity (in ‰)

The average ocean water chlorinity is about 19.2‰, and, thus, the average salinity is around 34.7‰.[116]

Salinity has a major influence on the density of seawater. A zone of rapid salinity increase with depth is called a halocline. As seawater's salt content increases, so does the temperature at which its maximum density occurs. Salinity affects both the freezing and boiling points of water, with the boiling point increasing with salinity. At atmospheric pressure,[117] normal seawater freezes at a temperature of about −2 °C.

Salinity is higher in Earth's oceans where there is more evaporation and lower where there is more precipitation. If precipitation exceeds evaporation, as is the case in polar and some temperate regions, salinity will be lower. Salinity will be higher if evaporation exceeds precipitation, as is sometimes the case in tropical regions. For example, evaporation is greater than precipitation in the Mediterranean Sea, which has an average salinity of 38‰, more saline than the global average of 34.7‰.[118] Thus, oceanic waters in polar regions have lower salinity content than oceanic waters in tropical regions.[116] However, when sea ice forms at high latitudes, salt is excluded from the ice as it forms, which can increase the salinity in the residual seawater in polar regions such as the Arctic Ocean.[89][119]

Due to the effects of climate change on oceans, observations of sea surface salinity between 1950 and 2019 indicate that regions of high salinity and evaporation have become more saline while regions of low salinity and more precipitation have become fresher.[120] It is very likely that the Pacific and Antarctic/Southern Oceans have freshened while the Atlantic has become more saline.[120]

Dissolved gases

Sea surface oxygen concentration in moles per cubic meter from the World Ocean Atlas[121]

Ocean water contains large quantities of dissolved gases, including oxygen, carbon dioxide and nitrogen. These dissolve into ocean water via gas exchange at the ocean surface, with the solubility of these gases depending on the temperature and salinity of the water.[16] The four most abundant gases in earth's atmosphere and oceans are nitrogen, oxygen, argon, and carbon dioxide. In the ocean by volume, the most abundant gases dissolved in seawater are carbon dioxide (including bicarbonate and carbonate ions, 14 mL/L on average), nitrogen (9 mL/L), and oxygen (5 mL/L) at equilibrium at 24 °C (75 °F)[122][123][124] All gases are more soluble – more easily dissolved – in colder water than in warmer water. For example, when salinity and pressure are held constant, oxygen concentration in water almost doubles when the temperature drops from that of a warm summer day 30 °C (86 °F) to freezing 0 °C (32 °F). Similarly, carbon dioxide and nitrogen gases are more soluble at colder temperatures, and their solubility changes with temperature at different rates.[122][125]

Oxygen, photosynthesis and carbon cycling

Diagram of the ocean carbon cycle showing the relative size of stocks (storage) and fluxes[126]

Photosynthesis in the surface ocean releases oxygen and consumes carbon dioxide. Phytoplankton, a type of microscopic free-floating algae, controls this process. After the plants have grown, oxygen is consumed and carbon dioxide released, as a result of bacterial decomposition of the organic matter created by photosynthesis in the ocean. The sinking and bacterial decomposition of some organic matter in deep ocean water, at depths where the waters are out of contact with the atmosphere, leads to a reduction in oxygen concentrations and increase in carbon dioxide, carbonate and bicarbonate.[98] This cycling of carbon dioxide in oceans is an important part of the global carbon cycle.

The oceans represent a major carbon sink for carbon dioxide taken up from the atmosphere by photosynthesis and by dissolution (see also carbon sequestration). There is also increased attention on carbon dioxide uptake in coastal marine habitats such as mangroves and saltmarshes. This process is often referred to as "Blue carbon". The focus is on these ecosystems because they are strong carbon sinks as well as ecologically important habitats under threat from human activities and environmental degradation.

As deep ocean water circulates throughout the globe, it contains gradually less oxygen and gradually more carbon dioxide with more time away from the air at the surface. This gradual decrease in oxygen concentration happens as sinking organic matter continuously gets decomposed during the time the water is out of contact with the atmosphere.[98] Most of the deep waters of the ocean still contain relatively high concentrations of oxygen sufficient for most animals to survive. However, some ocean areas have very low oxygen due to long periods of isolation of the water from the atmosphere. These oxygen deficient areas, called oxygen minimum zones or hypoxic waters, will generally be made worse by the effects of climate change on oceans.[127][128]

pH

The pH value at the surface of oceans (global mean surface pH) is currently approximately in the range of 8.05[129] to 8.08.[130] This makes it slightly alkaline. The pH value at the surface used to be about 8.2 during the past 300 million years.[131] However, between 1950 and 2020, the average pH of the ocean surface fell from approximately 8.15 to 8.05.[132] Carbon dioxide emissions from human activities are the primary cause of this process called ocean acidification, with atmospheric carbon dioxide (CO2) levels exceeding 410 ppm (in 2020).[133] CO2 from the atmosphere is absorbed by the oceans. This produces carbonic acid (H2CO3) which dissociates into a bicarbonate ion (HCO3) and a hydrogen ion (H+). The presence of free hydrogen ions (H+) lowers the pH of the ocean.

There is a natural gradient of pH in the ocean which is related to the breakdown of organic matter in deep water which slowly lowers the pH with depth: The pH value of seawater is naturally as low as 7.8 in deep ocean waters as a result of degradation of organic matter there.[134] It can be as high as 8.4 in surface waters in areas of high biological productivity.[98]

The definition of global mean surface pH refers to the top layer of the water in the ocean, up to around 20 or 100 m depth. In comparison, the average depth of the ocean is about 4 km. The pH value at greater depths (more than 100 m) has not yet been affected by ocean acidification in the same way. There is a large body of deeper water where the natural gradient of pH from 8.2 to about 7.8 still exists and it will take a very long time to acidify these waters, and equally as long to recover from that acidification. But as the top layer of the ocean (the photic zone) is crucial for its marine productivity, any changes to the pH value and temperature of the top layer can have many knock-on effects, for example on marine life and ocean currents (see also effects of climate change on oceans).[98]

The key issue in terms of the penetration of ocean acidification is the way the surface water mixes with deeper water or does not mix (a lack of mixing is called ocean stratification). This in turn depends on the water temperature and hence is different between the tropics and the polar regions (see ocean#Temperature).[98]

The chemical properties of seawater complicate pH measurement, and several distinct pH scales exist in chemical oceanography.[135] There is no universally accepted reference pH-scale for seawater and the difference between measurements based on multiple reference scales may be up to 0.14 units.[136]

Alkalinity

Alkalinity is the balance of base (proton acceptors) and acids (proton donors) in seawater, or indeed any natural waters. The alkalinity acts as a chemical buffer, regulating the pH of seawater. While there are many ions in seawater that can contribute to the alkalinity, many of these are at very low concentrations. This means that the carbonate, bicarbonate and borate ions are the only significant contributors to seawater alkalinity in the open ocean with well oxygenated waters. The first two of these ions contribute more than 95% of this alkalinity.[98]

The chemical equation for alkalinity in seawater is:

AT = [HCO3-] + 2[CO32-] + [B(OH)4-]

The growth of phytoplankton in surface ocean waters leads to the conversion of some bicarbonate and carbonate ions into organic matter. Some of this organic matter sinks into the deep ocean where it is broken down back into carbonate and bicarbonate. This process is related to ocean productivity or marine primary production. Thus alkalinity tends to increase with depth and also along the global thermohaline circulation from the Atlantic to the Pacific and Indian Ocean, although these increases are small. The concentrations vary overall by only a few percent.[98][134]

The absorption of CO2 from the atmosphere does not affect the ocean's alkalinity.[137]: 2252  It does lead to a reduction in pH value though (termed ocean acidification).[133]

Residence times of chemical elements and ions

Residence time of elements in the ocean depends on supply by processes like rock weathering and rivers vs. removal by processes like evaporation and sedimentation.

The ocean waters contain many chemical elements as dissolved ions. Elements dissolved in ocean waters have a wide range of concentrations. Some elements have very high concentrations of several grams per liter, such as sodium and chloride, together making up the majority of ocean salts. Other elements, such as iron, are present at tiny concentrations of just a few nanograms (10−9 grams) per liter.[116]

The concentration of any element depends on its rate of supply to the ocean and its rate of removal. Elements enter the ocean from rivers, the atmosphere and hydrothermal vents. Elements are removed from ocean water by sinking and becoming buried in sediments or evaporating to the atmosphere in the case of water and some gases. By estimating the residence time of an element, oceanographers examine the balance of input and removal. Residence time is the average time the element would spend dissolved in the ocean before it is removed. Heavily abundant elements in ocean water such as sodium, have high input rates. This reflects high abundance in rocks and rapid rock weathering, paired with very slow removal from the ocean due to sodium ions being comparatively unreactive and highly soluble. In contrast, other elements such as iron and aluminium are abundant in rocks but very insoluble, meaning that inputs to the ocean are low and removal is rapid. These cycles represent part of the major global cycle of elements that has gone on since the Earth first formed. The residence times of the very abundant elements in the ocean are estimated to be millions of years, while for highly reactive and insoluble elements, residence times are only hundreds of years.[116]

Residence times of elements and ions[138][139]
Chemical element or ion Residence time (years)
Chloride (Cl) 100,000,000
Sodium (Na+) 68,000,000
Magnesium (Mg2+) 13,000,000
Potassium (K+) 12,000,000
Sulfate (SO42−) 11,000,000
Calcium (Ca2+) 1,000,000
Carbonate (CO32−) 110,000
Silicon (Si) 20,000
Water (H2O) 4,100
Manganese (Mn) 1,300
Aluminum (Al) 600
Iron (Fe) 200

Nutrients

Map showing 5 circles. The first is between western Australia and eastern Africa. The second is between eastern Australia and western South America. The third is between Japan and western North America. Of the two in the Atlantic, one is in hemisphere.
North Atlantic
gyre
North Atlantic
gyre
North Atlantic
gyre
Indian
Ocean
gyre
North
Pacific
gyre
South
Pacific
gyre
South Atlantic
        gyre
Map showing 5 circles. The first is between western Australia and eastern Africa. The second is between eastern Australia and western South America. The third is between Japan and western North America. Of the two in the Atlantic, one is in hemisphere.
Ocean gyres rotate clockwise in the north and counterclockwise in the south.

A few elements such as nitrogen, phosphorus, iron, and potassium essential for life, are major components of biological material, and are commonly known as "nutrients". Nitrate and phosphate have ocean residence times of 10,000[140] and 69,000[141] years, respectively, while potassium is a much more abundant ion in the ocean with a residence time of 12 million[142] years. The biological cycling of these elements means that this represents a continuous removal process from the ocean's water column as degrading organic material sinks to the ocean floor as sediment.

Phosphate from intensive agriculture and untreated sewage is transported via runoff to rivers and coastal zones to the ocean where it is metabolized. Eventually, it sinks to the ocean floor and is no longer available to humans as a commercial resource.[143] Production of rock phosphate, an essential ingredient in inorganic fertilizer,[144] is a slow geological process that occurs in some of the world's ocean sediments, rendering mineable sedimentary apatite (phosphate) a non-renewable resource (see peak phosphorus). This continual net deposition loss of non-renewable phosphate from human activities, may become a resource issue for fertilizer production and food security in future.[145][146]

Marine life

Some representative ocean animals (not drawn to scale) within their approximate depth-defined ecological habitats. Marine microorganisms also exist on the surfaces and within the tissues and organs of the diverse life inhabiting the ocean, across all ocean habitats. The animals rooted to or living on the ocean floor are not pelagic but are benthic animals.[147]

Life within the ocean evolved 3 billion years prior to life on land. Both the depth and the distance from shore strongly influence the biodiversity of the plants and animals present in each region.[148] The diversity of life in the ocean is immense, including:

Killer whales (orcas) are highly visible marine apex predators that hunt many large species. But most biological activity in the ocean takes place with microscopic marine organisms that cannot be seen individually with the naked eye, such as marine bacteria and phytoplankton.[149]

Marine life, sea life or ocean life is the collective ecological communities that encompass all aquatic animals, plants, algae, fungi, protists, single-celled microorganisms and associated viruses living in the saline water of marine habitats, either the sea water of marginal seas and oceans, or the brackish water of coastal wetlands, lagoons, estuaries and inland seas. As of 2023, more than 242,000 marine species have been documented, and perhaps two million marine species are yet to be documented. An average of 2,332 new species per year are being described.[150][151] Marine life is studied scientifically in both marine biology and in biological oceanography.

Today, marine species range in size from the microscopic phytoplankton, which can be as small as 0.02–micrometres; to huge cetaceans like the blue whale, which can reach 33 m (108 ft) in length.[152][153] Marine microorganisms have been variously estimated as constituting about 70%[154] or about 90%[155][149] of the total marine biomass. Marine primary producers, mainly cyanobacteria and chloroplastic algae, produce oxygen and sequester carbon via photosynthesis, which generate enormous biomass and significantly influence the atmospheric chemistry. Migratory species, such as oceanodromous and anadromous fish, also create biomass and biological energy transfer between different regions of Earth, with many serving as keystone species of various ecosystems. At a fundamental level, marine life affects the nature of the planet, and in part, shape and protect shorelines, and some marine organisms (e.g. corals) even help create new land via accumulated reef-building.
A marine habitat is a habitat that supports marine life. Marine life depends in some way on the saltwater that is in the sea (the term marine comes from the Latin mare, meaning sea or ocean). A habitat is an ecological or environmental area inhabited by one or more living species.[156] The marine environment supports many kinds of these habitats.
Coral reefs form complex marine ecosystems with tremendous biodiversity.
Marine ecosystems are the largest of Earth's aquatic ecosystems and exist in waters that have a high salt content. These systems contrast with freshwater ecosystems, which have a lower salt content. Marine waters cover more than 70% of the surface of the Earth and account for more than 97% of Earth's water supply[157][158] and 90% of habitable space on Earth.[159] Seawater has an average salinity of 35 parts per thousand of water. Actual salinity varies among different marine ecosystems.[160] Marine ecosystems can be divided into many zones depending upon water depth and shoreline features. The oceanic zone is the vast open part of the ocean where animals such as whales, sharks, and tuna live. The benthic zone consists of substrates below water where many invertebrates live. The intertidal zone is the area between high and low tides. Other near-shore (neritic) zones can include mudflats, seagrass meadows, mangroves, rocky intertidal systems, salt marshes, coral reefs, lagoons. In the deep water, hydrothermal vents may occur where chemosynthetic sulfur bacteria form the base of the food web.

Human uses of the oceans

Global map of all exclusive economic zones

The ocean has been linked to human activity throughout history. These activities serve a wide variety of purposes, including navigation and exploration, naval warfare, travel, shipping and trade, food production (e.g. fishing, whaling, seaweed farming, aquaculture), leisure (cruising, sailing, recreational boat fishing, scuba diving), power generation (see marine energy and offshore wind power), extractive industries (offshore drilling and deep sea mining), freshwater production via desalination.

Many of the world's goods are moved by ship between the world's seaports.[161] Large quantities of goods are transported across the ocean, especially across the Atlantic and around the Pacific Rim.[162] Many types of cargo including manufactured goods, are typically transported in standard sized, lockable containers that are loaded on purpose-built container ships at dedicated terminals.[163] Containerization greatly boosted the efficiency and reduced the cost of shipping products by sea. This was a major factor in the rise of globalization and exponential increases in international trade in the mid-to-late 20th century.[164]

Oceans are also the major supply source for the fishing industry. Some of the major harvests are shrimp, fish, crabs, and lobster.[60] The biggest global commercial fishery is for anchovies, Alaska pollock and tuna.[165]: 6  A report by FAO in 2020 stated that "in 2017, 34 percent of the fish stocks of the world's marine fisheries were classified as overfished".[165]: 54  Fish and other fishery products from both wild fisheries and aquaculture are among the most widely consumed sources of protein and other essential nutrients. Data in 2017 showed that "fish consumption accounted for 17 percent of the global population's intake of animal proteins".[165] To fulfill this need, coastal countries have exploited marine resources in their exclusive economic zone. Fishing vessels are increasingly venturing out to exploit stocks in international waters.[166]

The ocean has a vast amount of energy carried by ocean waves, tides, salinity differences, and ocean temperature differences which can be harnessed to generate electricity.[167] Forms of sustainable marine energy include tidal power, ocean thermal energy and wave power.[167][168] Offshore wind power is captured by wind turbines placed out on the ocean; it has the advantage that wind speeds are higher than on land, though wind farms are more costly to construct offshore.[169] There are large deposits of petroleum, as oil and natural gas, in rocks beneath the ocean floor. Offshore platforms and drilling rigs extract the oil or gas and store it for transport to land.[170]

"Freedom of the seas" is a principle in international law dating from the seventeenth century. It stresses freedom to navigate the oceans and disapproves of war fought in international waters.[171] Today, this concept is enshrined in the United Nations Convention on the Law of the Sea (UNCLOS).[171]

The International Maritime Organization (IMO), which was ratified in 1958, is mainly responsible for maritime safety, liability and compensation, and has held some conventions on marine pollution related to shipping incidents. Ocean governance is the conduct of the policy, actions and affairs regarding the world's oceans.[172]

Threats from human activities

Global cumulative human impact on the ocean[173]

Human activities affect marine life and marine habitats through many negative influences, such as marine pollution (including marine debris and microplastics) overfishing, ocean acidification and other effects of climate change on oceans.

Climate change

There are many effects of climate change on oceans. One of the main ones is an increase in ocean temperatures. More frequent marine heatwaves are linked to this. The rising temperature contributes to a rise in sea levels due to melting ice sheets. Other effects on oceans include sea ice decline, reducing pH values and oxygen levels, as well as increased ocean stratification. All this can lead to changes of ocean currents, for example a weakening of the Atlantic meridional overturning circulation (AMOC).[99] The main root cause of these changes are the emissions of greenhouse gases from human activities, mainly burning of fossil fuels. Carbon dioxide and methane are examples of greenhouse gases. The additional greenhouse effect leads to ocean warming because the ocean takes up most of the additional heat in the climate system.[174] The ocean also absorbs some of the extra carbon dioxide that is in the atmosphere. This causes the pH value of the seawater to drop.[175] Scientists estimate that the ocean absorbs about 25% of all human-caused CO2 emissions.[175]

The various layers of the oceans have different temperatures. For example, the water is colder towards the bottom of the ocean. This temperature stratification will increase as the ocean surface warms due to rising air temperatures.[176]: 471  Connected to this is a decline in mixing of the ocean layers, so that warm water stabilises near the surface. A reduction of cold, deep water circulation follows. The reduced vertical mixing makes it harder for the ocean to absorb heat. So a larger share of future warming goes into the atmosphere and land. One result is an increase in the amount of energy available for tropical cyclones and other storms. Another result is a decrease in nutrients for fish in the upper ocean layers. These changes also reduce the ocean's capacity to store carbon.[177] At the same time, contrasts in salinity are increasing. Salty areas are becoming saltier and fresher areas less salty.[178]

Warmer water cannot contain the same amount of oxygen as cold water. As a result, oxygen from the oceans moves to the atmosphere. Increased thermal stratification may reduce the supply of oxygen from surface waters to deeper waters. This lowers the water's oxygen content even more.[179] The ocean has already lost oxygen throughout its water column. Oxygen minimum zones are increasing in size worldwide.[176]: 471 

These changes harm marine ecosystems, and this can lead to biodiversity loss or changes in species distribution.[99] This in turn can affect fishing and coastal tourism. For example, rising water temperatures are harming tropical coral reefs. The direct effect is coral bleaching on these reefs, because they are sensitive to even minor temperature changes. So a small increase in water temperature could have a significant impact in these environments. Another example is loss of sea ice habitats due to warming. This will have severe impacts on polar bears and other animals that rely on it. The effects of climate change on oceans put additional pressures on ocean ecosystems which are already under pressure by other impacts from human activities.[99]

Marine pollution

Marine pollution occurs when substances used or spread by humans, such as industrial, agricultural and residential waste, particles, noise, excess carbon dioxide or invasive organisms enter the ocean and cause harmful effects there. The majority of this waste (80%) comes from land-based activity, although marine transportation significantly contributes as well.[180] It is a combination of chemicals and trash, most of which comes from land sources and is washed or blown into the ocean. This pollution results in damage to the environment, to the health of all organisms, and to economic structures worldwide.[181] Since most inputs come from land, either via the rivers, sewage or the atmosphere, it means that continental shelves are more vulnerable to pollution. Air pollution is also a contributing factor by carrying off iron, carbonic acid, nitrogen, silicon, sulfur, pesticides or dust particles into the ocean.[182] The pollution often comes from nonpoint sources such as agricultural runoff, wind-blown debris, and dust. These nonpoint sources are largely due to runoff that enters the ocean through rivers, but wind-blown debris and dust can also play a role, as these pollutants can settle into waterways and oceans.[183] Pathways of pollution include direct discharge, land runoff, ship pollution, bilge pollution, atmospheric pollution and, potentially, deep sea mining.

The types of marine pollution can be grouped as pollution from marine debris, plastic pollution, including microplastics, ocean acidification, nutrient pollution, toxins and underwater noise. Plastic pollution in the ocean is a type of marine pollution by plastics, ranging in size from large original material such as bottles and bags, down to microplastics formed from the fragmentation of plastic material. Marine debris is mainly discarded human rubbish which floats on, or is suspended in the ocean. Plastic pollution is harmful to marine life.

Another concern is the runoff of nutrients (nitrogen and phosphorus) from intensive agriculture, and the disposal of untreated or partially treated sewage to rivers and subsequently oceans. These nitrogen and phosphorus nutrients (which are also contained in fertilizers) stimulate phytoplankton and macroalgal growth, which can lead to harmful algal blooms (eutrophication) which can be harmful to humans as well as marine creatures. Excessive algal growth can also smother sensitive coral reefs and lead to loss of biodiversity and coral health. A second major concern is that the degradation of algal blooms can lead to consumption of oxygen in coastal waters, a situation that may worsen with climate change as warming reduces vertical mixing of the water column.[184]

Many potentially toxic chemicals adhere to tiny particles which are then taken up by plankton and benthic animals, most of which are either deposit feeders or filter feeders. In this way, the toxins are concentrated upward within ocean food chains. When pesticides are incorporated into the marine ecosystem, they quickly become absorbed into marine food webs. Once in the food webs, these pesticides can cause mutations, as well as diseases, which can be harmful to humans as well as the entire food web. Toxic metals can also be introduced into marine food webs. These can cause a change to tissue matter, biochemistry, behavior, reproduction, and suppress growth in marine life. Also, many animal feeds have a high fish meal or fish hydrolysate content. In this way, marine toxins can be transferred to land animals, and appear later in meat and dairy products.

Overfishing

Overfishing is the removal of a species of fish (i.e. fishing) from a body of water at a rate greater than that the species can replenish its population naturally (i.e. the overexploitation of the fishery's existing fish stock), resulting in the species becoming increasingly underpopulated in that area. Overfishing can occur in water bodies of any sizes, such as ponds, wetlands, rivers, lakes or oceans, and can result in resource depletion, reduced biological growth rates and low biomass levels. Sustained overfishing can lead to critical depensation, where the fish population is no longer able to sustain itself. Some forms of overfishing, such as the overfishing of sharks, has led to the upset of entire marine ecosystems.[185] Types of overfishing include growth overfishing, recruitment overfishing, and ecosystem overfishing. Overfishing not only causes negative impacts on biodiversity and ecosystem functioning, but also reduces fish production, which subsequently leads to negative social and economic consequences.[186]

Protection

Ocean protection serves to safeguard the ecosystems in the oceans upon which humans depend.[187][188] Protecting these ecosystems from threats is a major component of environmental protection. One of protective measures is the creation and enforcement of marine protected areas (MPAs). Marine protection may need to be considered within a national, regional and international context.[189] Other measures include supply chain transparency requirement policies, policies to prevent marine pollution, ecosystem-assistance (e.g. for coral reefs) and support for sustainable seafood (e.g. sustainable fishing practices and types of aquaculture). There is also the protection of marine resources and components whose extraction or disturbance would cause substantial harm, engagement of broader publics and impacted communities,[190] and the development of ocean clean-up projects (removal of marine plastic pollution). Examples of the latter include Clean Oceans International and The Ocean Cleanup.

In 2021, 43 expert scientists published the first scientific framework version that – via integration, review, clarifications and standardization – enables the evaluation of levels of protection of marine protected areas and can serve as a guide for any subsequent efforts to improve, plan and monitor marine protection quality and extents. Examples are the efforts towards the 30%-protection-goal of the "Global Deal For Nature"[191] and the UN's Sustainable Development Goal 14 ("life below water").[192][193]

In March 2023 a High Seas Treaty was signed. It is legally binding. The main achievement is the new possibility to create marine protected areas in international waters. By doing so the agreement now makes it possible to protect 30% of the oceans by 2030 (part of the 30 by 30 target).[194][195] The treaty has articles regarding the principle "polluter-pays", and different impacts of human activities including areas beyond the national jurisdiction of the countries making those activities. The agreement was adopted by the 193 United Nations Member States.[196]

See also

References

  1. ^ a b Webb, Paul. "1.1 Overview of the Oceans". Roger Williams University Open Publishing – Driving learning and savings, simultaneously. Retrieved May 10, 2023.
  2. ^ "How deep is the ocean?". NOAA's National Ocean Service. Retrieved May 10, 2023.
  3. ^ "Challenger Deep – the Mariana Trench". Archived from the original on April 24, 2006. Retrieved July 30, 2012.
  4. ^ "Coastline – The World Factbook". Central Intelligence Agency.
  5. ^ "Coastal and Marine Ecosystems – Marine Jurisdictions: Coastline length". World Resources Institute. Archived from the original on April 19, 2012. Retrieved March 18, 2012.
  6. ^ a b "How does the temperature of ocean water vary? : Ocean Exploration Facts: NOAA Office of Ocean Exploration and Research". Home. March 5, 2013. Retrieved May 10, 2023.
  7. ^ a b "Voyager: How Long until Ocean Temperature Goes up a Few More Degrees?". Scripps Institution of Oceanography. March 18, 2014. Retrieved May 10, 2023.
  8. ^ a b c "8(o) Introduction to the Oceans". www.physicalgeography.net.
  9. ^ "Ocean." Merriam-Webster.com Dictionary, Merriam-Webster, https://www.merriam-webster.com/dictionary/ocean . Accessed March 14, 2021.
  10. ^ a b "ocean, n". Oxford English Dictionary. Retrieved February 5, 2012.
  11. ^ a b "ocean". Merriam-Webster. Retrieved February 6, 2012.
  12. ^ a b c d Bigg, Grant R. (2003). The Oceans and Climate, Second Edition (2 ed.). Cambridge: Cambridge University Press. doi:10.1017/cbo9781139165013. ISBN 978-1-139-16501-3.
  13. ^ "How much oxygen comes from the ocean?". National Ocean Service. National Oceanic and Atmospheric Administration U.S. Department of Commerce. February 26, 2021. Retrieved November 3, 2021.
  14. ^ a b Gordon, Arnold (2004). "Ocean Circulation". The Climate System. Columbia University. Retrieved July 6, 2013.
  15. ^ a b NOAA, NOAA. "What is a current?". Ocean Service Noaa. National Ocean Service. Retrieved December 13, 2020.
  16. ^ a b Chester, R.; Jickells, Tim (2012). "Chapter 8: Air–sea gas exchange". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. ISBN 978-1-118-34909-0. OCLC 781078031.
  17. ^ IUCN (2017) The Ocean and Climate Change , IUCN (International Union for Conservation of Nature) Issues Brief.
  18. ^ Drogin, Bob (August 2, 2009). "Mapping an ocean of species". Los Angeles Times. Retrieved August 18, 2009.
  19. ^ "Sea". Merriam-webster.com. Retrieved March 13, 2013.
  20. ^ Bromhead, Helen, Landscape and Culture – Cross-linguistic Perspectives, p. 92, John Benjamins Publishing Company, 2018, ISBN 978-9027264008; unlike Americans, speakers of British English do not go swimming in "the ocean" but always "the sea".
  21. ^ "WordNet Search – sea". Princeton University. Retrieved February 21, 2012.
  22. ^ "What's the difference between an ocean and a sea?". Ocean facts. National Oceanic and Atmospheric Administration. Retrieved April 19, 2013.
  23. ^ a b Janin, H.; Mandia, S.A. (2012). Rising Sea Levels: An Introduction to Cause and Impact. McFarland, Incorporated, Publishers. p. 20. ISBN 978-0-7864-5956-8. Retrieved August 26, 2022.
  24. ^ Bruckner, Lynne and Dan Brayton (2011). Ecocritical Shakespeare (Literary and Scientific Cultures of Early Modernity). Ashgate Publishing, Ltd. ISBN 978-0754669197.
  25. ^ a b Ro, Christine (February 3, 2020). "Is It Ocean Or Oceans?". Forbes. Retrieved August 26, 2022.
  26. ^ "Ocean". Sciencedaily.com. Archived from the original on April 24, 2015. Retrieved November 8, 2012.
  27. ^ a b ""Distribution of land and water on the planet". UN Atlas of the Oceans. Archived from the original on March 3, 2016.
  28. ^ Spilhaus, Athelstan F. (July 1942). "Maps of the whole world ocean". Geographical Review. 32 (3): 431–435. Bibcode:1942GeoRv..32..431S. doi:10.2307/210385. ISSN 0016-7428. JSTOR 210385.
  29. ^ Ὠκεανός, Henry George Liddell, Robert Scott, A Greek-English Lexicon, at Perseus project
  30. ^ Matasović, Ranko, A Reader in Comparative Indo-European Religion Zagreb: Univ of Zagreb, 2016. page 20.
  31. ^ Drake, Michael J. (2005), "Origin of water in the terrestrial planets", Meteoritics & Planetary Science, 40 (4): 515–656, Bibcode:2005M&PS...40..515J, doi:10.1111/j.1945-5100.2005.tb00958.x, S2CID 247695232.
  32. ^ "Why do we have an ocean?". NOAA's National Ocean Service. June 1, 2013. Retrieved September 3, 2022.
  33. ^ "NASA Astrobiology". Astrobiology. June 5, 2017. Retrieved September 13, 2022.
  34. ^ a b Pinti, Daniele L.; Arndt, Nicholas (2014), "Oceans, Origin of", Encyclopedia of Astrobiology, Springer Berlin Heidelberg, pp. 1–5, doi:10.1007/978-3-642-27833-4_1098-4, ISBN 978-3642278334
  35. ^ Cates, N.L.; Mojzsis, S.J. (March 2007). "Pre-3750 Ma supracrustal rocks from the Nuvvuagittuq supracrustal belt, northern Québec". Earth and Planetary Science Letters. 255 (1–2): 9–21. Bibcode:2007E&PSL.255....9C. doi:10.1016/j.epsl.2006.11.034. ISSN 0012-821X.
  36. ^ O'Neil, Jonathan; Carlson, Richard W.; Paquette, Jean-Louis; Francis, Don (November 2012). "Formation age and metamorphic history of the Nuvvuagittuq Greenstone Belt" (PDF). Precambrian Research. 220–221: 23–44. Bibcode:2012PreR..220...23O. doi:10.1016/j.precamres.2012.07.009. ISSN 0301-9268. S2CID 128825728.
  37. ^ Washington University in St. Louis (August 27, 2020). "Meteorite study suggests Earth may have been wet since it formed – Enstatite chondrite meteorites, once considered 'dry,' contain enough water to fill the oceans – and then some". EurekAlert!. Retrieved August 28, 2020.
  38. ^ American Association for the Advancement of Science (August 27, 2020). "Unexpected abundance of hydrogen in meteorites reveals the origin of Earth's water". EurekAlert!. Retrieved August 28, 2020.
  39. ^ Piani, Laurette; Marrocchi, Yves; Rigaudier, Thomas; Vacher, Lionel G.; Thomassin, Dorian; Marty, Bernard (2020). "Earth's water may have been inherited from material similar to enstatite chondrite meteorites". Science. 369 (6507): 1110–1113. Bibcode:2020Sci...369.1110P. doi:10.1126/science.aba1948. ISSN 0036-8075. PMID 32855337. S2CID 221342529.
  40. ^ Guinan, E. F.; Ribas, I. (2002). Benjamin Montesinos, Alvaro Gimenez and Edward F. Guinan (ed.). Our Changing Sun: The Role of Solar Nuclear Evolution and Magnetic Activity on Earth's Atmosphere and Climate. ASP Conference Proceedings: The Evolving Sun and its Influence on Planetary Environments. San Francisco: Astronomical Society of the Pacific. Bibcode:2002ASPC..269...85G. ISBN 978-1-58381-109-2.
  41. ^ a b Voosen, Paul (March 9, 2021). "Ancient Earth was a water world". Science. 371 (6534). American Association for the Advancement of Science (AAAS): 1088–1089. doi:10.1126/science.abh4289. ISSN 0036-8075. PMID 33707245. S2CID 241687784.
  42. ^ "The Water Cycle summary". USGS Water Science School. Archived from the original on January 16, 2018. Retrieved January 15, 2018.
  43. ^ Smith, Yvette (June 7, 2021). "Earth Is a Water World". NASA. Retrieved August 27, 2022.
  44. ^ "Water-Worlds". National Geographic Society. May 20, 2022. Retrieved August 24, 2022.
  45. ^ Lunine, Jonathan I. (2017). "Ocean worlds exploration". Acta Astronautica. 131. Elsevier BV: 123–130. Bibcode:2017AcAau.131..123L. doi:10.1016/j.actaastro.2016.11.017. ISSN 0094-5765.
  46. ^ "Ocean Worlds". Ocean Worlds. Archived from the original on August 27, 2022. Retrieved August 27, 2022.
  47. ^ "Where is Point Nemo?". NOAA. Retrieved February 20, 2015.
  48. ^ a b "Recommendation ITU-R RS.1624: Sharing between the Earth exploration-satellite (passive) and airborne altimeters in the aeronautical radionavigation service in the band 4 200–4 400 MHz (Question ITU-R 229/7)" (PDF). ITU Radiotelecommunication Sector (ITU-R). Retrieved April 5, 2015. The oceans occupy about 3.35×108 km2 of area. There are 377412 km of oceanic coastlines in the world.
  49. ^ a b "Pacific Ocean". Encyclopedia of Earth. Retrieved March 7, 2015.
  50. ^ a b "Atlantic Ocean". Encyclopedia of Earth. Retrieved March 7, 2015.
  51. ^ a b "Indian Ocean". Encyclopedia of Earth. Retrieved March 7, 2015.
  52. ^ a b "Southern Ocean". Encyclopedia of Earth. Retrieved March 10, 2015.
  53. ^ a b "Limits of Oceans and Seas, 3rd edition" (PDF). International Hydrographic Organization. 1953. Archived from the original (PDF) on October 8, 2011. Retrieved December 28, 2020.
  54. ^ a b Tomczak, Matthias; Godfrey, J. Stuart (2003). Regional Oceanography: an Introduction (2 ed.). Delhi: Daya Publishing House. ISBN 978-81-7035-306-5. Archived from the original on June 30, 2007. Retrieved April 10, 2006.
  55. ^ a b Ostenso, Ned Allen. "Arctic Ocean". Encyclopædia Britannica. Retrieved July 2, 2012. As an approximation, the Arctic Ocean may be regarded as an estuary of the Atlantic Ocean.
  56. ^ a b "Arctic Ocean". Encyclopedia of Earth. Retrieved March 7, 2015.
  57. ^ Pidwirny, Michael (March 28, 2013). "Plate tectonics". The Encyclopedia of Earth. Archived from the original on October 21, 2014. Retrieved September 20, 2013.
  58. ^ "Plate Tectonics: The Mechanism". University of California Museum of Paleontology. Archived from the original on July 30, 2014. Retrieved September 20, 2013.
  59. ^ "What is the longest mountain range on earth?". National Ocean Service. US Department of Commerce. Retrieved October 17, 2014.
  60. ^ a b c "NOAA – National Oceanic and Atmospheric Administration – Ocean". Noaa.gov. Retrieved February 16, 2020.
  61. ^ a b c d Monkhouse, F. J. (1975). Principles of Physical Geography. Hodder & Stoughton. pp. 280–291. ISBN 978-0-340-04944-0.
  62. ^ Whittow, John B. (1984). The Penguin Dictionary of Physical Geography. Penguin Books. pp. 29, 80, 246. ISBN 978-0-14-051094-2.
  63. ^ "Thames Barrier engineer says second defence needed". BBC News. January 5, 2013. Archived from the original on September 26, 2013. Retrieved September 18, 2013.
  64. ^ Fleming, Nic (May 27, 2015). "Is the sea really blue?". BBC - Earth. BBC. Retrieved August 25, 2021.
  65. ^ Webb, Paul (July 2020), "6.5 Light", Introduction to Oceanography, retrieved July 21, 2021
  66. ^ Morel, Andre; Prieur, Louis (1977). "Analysis of variations in ocean color 1". Limnology and Oceanography. 22 (4): 709–722. Bibcode:1977LimOc..22..709M. doi:10.4319/lo.1977.22.4.0709.
  67. ^ Coble, Paula G. (2007). "Marine Optical Biogeochemistry: The Chemistry of Ocean Color". Chemical Reviews. 107 (2): 402–418. doi:10.1021/cr050350+. PMID 17256912.
  68. ^ a b "The Water Cycle: The Oceans". US Geological Survey. Retrieved July 17, 2021.
  69. ^ King, Michael D.; Platnick, Steven; Menzel, W. Paul; Ackerman, Steven A.; Hubanks, Paul A. (2013). "Spatial and Temporal Distribution of Clouds Observed by MODIS Onboard the Terra and Aqua Satellites". IEEE Transactions on Geoscience and Remote Sensing. 51 (7). Institute of Electrical and Electronics Engineers (IEEE): 3826–3852. Bibcode:2013ITGRS..51.3826K. doi:10.1109/tgrs.2012.2227333. hdl:2060/20120010368. ISSN 0196-2892. S2CID 206691291.
  70. ^ Observation of swell dissipation across oceans, F. Ardhuin, Collard, F., and B. Chapron, 2009: Geophys. Res. Lett. 36, L06607, doi:10.1029/2008GL037030
  71. ^ Stow, Dorrik (2004). Encyclopedia of the Oceans. Oxford University Press. ISBN 978-0-19-860687-1.
  72. ^ a b c d "Volumes of the World's Oceans from ETOPO1". NOAA. Archived from the original on March 11, 2015. Retrieved March 7, 2015.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
  73. ^ Young, I. R. (1999). Wind Generated Ocean Waves. Elsevier. p. 83. ISBN 978-0-08-043317-2.
  74. ^ a b c Garrison, Tom (2012). Essentials of Oceanography. 6th ed. pp. 204 ff. Brooks/Cole, Belmont. ISBN 0321814053.
  75. ^ National Meteorological Library and Archive (2010). "Fact Sheet 6 – The Beaufort Scale". Met Office (Devon)
  76. ^ Holliday, N. P.; Yelland, M. J.; Pascal, R.; Swail, V. R.; Taylor, P. K.; Griffiths, C. R.; Kent, E. (2006). "Were extreme waves in the Rockall Trough the largest ever recorded?". Geophysical Research Letters. 33 (5): L05613. Bibcode:2006GeoRL..33.5613H. doi:10.1029/2005GL025238.
  77. ^ Laird, Anne (2006). "Observed Statistics of Extreme Waves". Naval Postgraduate School (Monterey).
  78. ^ "Ocean waves". Ocean Explorer. National Oceanic and Atmospheric Administration. Retrieved April 17, 2013.
  79. ^ "Life of a Tsunami". Tsunamis & Earthquakes. US Geological Survey. Retrieved July 14, 2021.
  80. ^ "Physics of Tsunamis". National Tsunami Warning Center of the USA. Retrieved July 14, 2021.
  81. ^ "Tides". Ocean Explorer. National Oceanic and Atmospheric Administration. Retrieved April 20, 2013.
  82. ^ a b "Tides and Water Levels". NOAA Oceans and Coasts. NOAA Ocean Service Education. Retrieved April 20, 2013.
  83. ^ "Tidal amplitudes". University of Guelph. Retrieved September 12, 2013.
  84. ^ "Chapter 8. Gravity Waves, Tides, and Coastal Oceanography". Descriptive physical oceanography : an introduction. Lynne D. Talley, George L. Pickard, William J. Emery, James H. Swift (6th ed.). Amsterdam: Academic Press. 2011. ISBN 978-0-7506-4552-2. OCLC 720651296.{{cite book}}: CS1 maint: others (link)
  85. ^ "Weird Science: Extreme Tidal Ranges". Exploring Our Fluid Earth: Teaching Science as Inquiry. University of Hawaiʻi. Retrieved November 9, 2021.
  86. ^ "Where are the Highest Tides in the World?". Casual Navigation. Retrieved November 9, 2021.
  87. ^ Drazen, Jeffrey C. "Deep-Sea Fishes". School of Ocean and Earth Science and Technology, the University of Hawaiʻi at Mānoa. Archived from the original on May 24, 2012. Retrieved June 7, 2007.
  88. ^ "Scientists map Mariana Trench, deepest known section of ocean in the world". The Telegraph. Telegraph Media Group. December 7, 2011. Archived from the original on December 8, 2011. Retrieved March 23, 2012.
  89. ^ a b c d e f g "Chapter 3. Physical Properties of Seawater". Descriptive physical oceanography : an introduction. Lynne D. Talley, George L. Pickard, William J. Emery, James H. Swift (6th ed.). Amsterdam: Academic Press. 2011. ISBN 978-0-7506-4552-2. OCLC 720651296.{{cite book}}: CS1 maint: others (link)
  90. ^ "What is a thermocline?". National Ocean Service. US Department of Commerce. Retrieved February 7, 2021.
  91. ^ Qadri, Syed (2003). "Volume of Earth's Oceans". The Physics Factbook. Retrieved June 7, 2007.
  92. ^ Charette, Matthew; Smith, Walter H. F. (2010). "The volume of Earth's ocean". Oceanography. 23 (2): 112–114. doi:10.5670/oceanog.2010.51. hdl:1912/3862.
  93. ^ Where is Earth's water?, United States Geological Survey.
  94. ^ Eakins, B.W. and G.F. Sharman, Volumes of the World's Oceans from ETOPO1, NOAA National Geophysical Data Center, Boulder, CO, 2010.
  95. ^ Water in Crisis: Chapter 2, Peter H. Gleick, Oxford University Press, 1993.
  96. ^ World Water Resources: A New Appraisal and Assessment for the 21st Century (Report). UNESCO. 1998. Archived from the original on September 27, 2013. Retrieved June 13, 2013.
  97. ^ Kennish, Michael J. (2001). Practical handbook of marine science. Marine science series (3rd ed.). CRC Press. p. 35. ISBN 0-8493-2391-6.
  98. ^ a b c d e f g h Chester, R.; Jickells, Tim (2012). "Chapter 9: Nutrients, oxygen, organic carbon and the carbon cycle in seawater". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. ISBN 978-1-118-34909-0. OCLC 781078031.
  99. ^ a b c d "Summary for Policymakers". The Ocean and Cryosphere in a Changing Climate (PDF). 2019. pp. 3–36. doi:10.1017/9781009157964.001. ISBN 978-1-00-915796-4. Archived (PDF) from the original on March 29, 2023. Retrieved March 26, 2023.
  100. ^ a b c Cheng, Lijing; Abraham, John; Trenberth, Kevin E.; Fasullo, John; Boyer, Tim; Mann, Michael E.; Zhu, Jiang; Wang, Fan; Locarnini, Ricardo; Li, Yuanlong; Zhang, Bin; Yu, Fujiang; Wan, Liying; Chen, Xingrong; Feng, Licheng (2023). "Another Year of Record Heat for the Oceans". Advances in Atmospheric Sciences. 40 (6): 963–974. Bibcode:2023AdAtS..40..963C. doi:10.1007/s00376-023-2385-2. ISSN 0256-1530. PMC 9832248. PMID 36643611. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  101. ^ Fox-Kemper, B., H.T. Hewitt, C. Xiao, G. Aðalgeirsdóttir, S.S. Drijfhout, T.L. Edwards, N.R. Golledge, M. Hemer, R.E. Kopp, G. Krinner, A. Mix, D. Notz, S. Nowicki, I.S. Nurhati, L. Ruiz, J.-B. Sallée, A.B.A. Slangen, and Y. Yu, 2021: Chapter 9: Ocean, Cryosphere and Sea Level Change Archived 2022-10-24 at the Wayback Machine. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 2021-08-09 at the Wayback Machine [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1211–1362
  102. ^ "IPCC Fourth Assessment Report: Climate Change 2007, Working Group I: The Physical Science Basis, 5.6 Synthesis". IPCC (archive). Retrieved July 19, 2021.
  103. ^ "Evaporation minus precipitation, Latitude-Longitude, Annual mean". ERA-40 Atlas. ECMWF. Archived from the original on February 2, 2014.
  104. ^ Barry, Roger Graham; Chorley, Richard J. (2003). Atmosphere, Weather, and Climate. Routledge. p. 68. ISBN 978-0203440513.
  105. ^ Deser, C.; Alexander, M. A.; Xie, S. P.; Phillips, A. S. (2010). "Sea Surface Temperature Variability: Patterns and Mechanisms" (PDF). Annual Review of Marine Science. 2: 115–143. Bibcode:2010ARMS....2..115D. doi:10.1146/annurev-marine-120408-151453. PMID 21141660. Archived from the original (PDF) on May 14, 2014.
  106. ^ Huang, Rui Xin (2010). Ocean circulation : wind-driven and thermohaline processes. Cambridge: Cambridge University Press. ISBN 978-0-511-68849-2. OCLC 664005236.
  107. ^ Jeffries, Martin O. (2012). "Sea ice". Encyclopedia Britannica. Britannica Online Encyclopedia. Retrieved April 21, 2013.
  108. ^ Wadhams, Peter (January 1, 2003). "How Does Arctic Sea Ice Form and Decay?". Arctic theme page. NOAA. Archived from the original on March 6, 2005. Retrieved April 25, 2005.
  109. ^ Weeks, Willy F. (2010). On Sea Ice. University of Alaska Press. p. 2. ISBN 978-1-60223-101-6.
  110. ^ Shokr, Mohammed; Sinha, Nirmal (2015). Sea Ice – Physics and Remote Sensing. John Wiley & Sons, Inc. ISBN 978-1119027898.
  111. ^ "Sea Ice". National Snow and Ice Data Center. Retrieved November 22, 2022.
  112. ^ "Tidal Currents – Currents: NOAA's National Ocean Service Education". National Ocean Service. US Department of Commerce. Retrieved February 7, 2021.
  113. ^ a b c d e "Chapter 7. Dynamical Processes for Descriptive Ocean Circulation". Descriptive physical oceanography : an introduction. Lynne D. Talley, George L. Pickard, William J. Emery, James H. Swift (6th ed.). Amsterdam: Academic Press. 2011. ISBN 978-0-7506-4552-2. OCLC 720651296.{{cite book}}: CS1 maint: others (link)
  114. ^ a b IPCC, 2019: Summary for Policymakers. In: IPCC Special Report on the Ocean and Cryosphere in a Changing Climate [H.-O. Pörtner, D.C. Roberts, V. Masson-Delmotte, P. Zhai, M. Tignor, E. Poloczanska, K. Mintenbeck, A. Alegría, M. Nicolai, A. Okem, J. Petzold, B. Rama, N.M. Weyer (eds.)]. Cambridge University Press, Cambridge and New York. doi:10.1017/9781009157964.001.
  115. ^ Baranova, Olga. "World Ocean Atlas 2009". National Centers for Environmental Information (NCEI). Retrieved January 18, 2022.
  116. ^ a b c d e Chester, R.; Jickells, Tim (2012). "Chapter 7: Descriptive oceanography: water-column parameters". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. ISBN 978-1-118-34909-0. OCLC 781078031.
  117. ^ "Can the ocean freeze? Ocean water freezes at a lower temperature than freshwater". NOAA. Archived from the original on July 6, 2020. Retrieved January 2, 2019.
  118. ^ "Hydrologic features and climate". Encyclopedia Britannica. Retrieved January 18, 2022.
  119. ^ "Salinity and Brine". National Snow and Ice Data Center. Retrieved January 18, 2022.
  120. ^ a b Fox-Kemper, B., H.T. Hewitt, C. Xiao, G. Aðalgeirsdóttir, S.S. Drijfhout, T.L. Edwards, N.R. Golledge, M. Hemer, R.E. Kopp, G. Krinner, A. Mix, D. Notz, S. Nowicki, I.S. Nurhati, L. Ruiz, J.-B. Sallée, A.B.A. Slangen, and Y. Yu, 2021: Chapter 9: Ocean, Cryosphere and Sea Level Change. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, New York, USA, pages 1211–1362, doi:10.1017/9781009157896.011
  121. ^ Garcia, H.E.; Locarnini, R.A.; Boyer, T.P.; Antonov, J.I. (2006). Levitus, S. (ed.). World Ocean Atlas 2005, Volume 3: Dissolved Oxygen, Apparent Oxygen Utilization, and Oxygen Saturation. Washington, D.C.: NOAA Atlas NESDIS 63, U.S. Government Printing Office. p. 342.
  122. ^ a b "The seawater solution". Seawater. Elsevier. 1995. pp. 85–127. doi:10.1016/b978-075063715-2/50007-1. ISBN 978-0750637152.
  123. ^ "Dissolved Gases other than Carbon Dioxide in Seawater" (PDF). soest.hawaii.edu. Retrieved May 5, 2014.
  124. ^ "Dissolved Oxygen and Carbon Dioxide" (PDF). chem.uiuc.edu. Archived from the original (PDF) on June 12, 2014. Retrieved February 3, 2014.
  125. ^ "12.742. Marine Chemistry. Lecture 8. Dissolved Gases and Air-sea exchange" (PDF). Retrieved May 5, 2014.
  126. ^ "Ocean carbon cycle". GRID-Arendal. June 5, 2009. Retrieved January 18, 2022.
  127. ^ Breitburg, Denise; Levin, Lisa A.; Oschlies, Andreas; Grégoire, Marilaure; Chavez, Francisco P.; Conley, Daniel J.; Garçon, Véronique; Gilbert, Denis; Gutiérrez, Dimitri; Isensee, Kirsten; Jacinto, Gil S. (January 5, 2018). "Declining oxygen in the global ocean and coastal waters". Science. 359 (6371): eaam7240. Bibcode:2018Sci...359M7240B. doi:10.1126/science.aam7240. ISSN 0036-8075. PMID 29301986.
  128. ^ Karstensen, J; Stramma, L; Visbeck, M (2008). "Oxygen minimum zones in the eastern tropical Atlantic and Pacific oceans" (PDF). Progress in Oceanography. 77 (4): 331–350. Bibcode:2008PrOce..77..331K. doi:10.1016/j.pocean.2007.05.009.
  129. ^ Terhaar, Jens; Frölicher, Thomas L.; Joos, Fortunat (2023). "Ocean acidification in emission-driven temperature stabilization scenarios: the role of TCRE and non-CO2 greenhouse gases". Environmental Research Letters. 18 (2): 024033. Bibcode:2023ERL....18b4033T. doi:10.1088/1748-9326/acaf91. ISSN 1748-9326. S2CID 255431338. Figure 1f
  130. ^ Arias, P.A., N. Bellouin, E. Coppola, R.G. Jones, G. Krinner, J. Marotzke, V. Naik, M.D. Palmer, G.-K. Plattner, J. Rogelj, M. Rojas, J. Sillmann, T. Storelvmo, P.W. Thorne, B. Trewin, K. Achuta Rao, B. Adhikary, R.P. Allan, K. Armour, G. Bala, R. Barimalala, S. Berger, J.G. Canadell, C. Cassou, A. Cherchi, W. Collins, W.D. Collins, S.L. Connors, S. Corti, F. Cruz, F.J. Dentener, C. Dereczynski, A. Di Luca, A. Diongue Niang, F.J. Doblas-Reyes, A. Dosio, H. Douville, F. Engelbrecht, V.  Eyring, E. Fischer, P. Forster, B. Fox-Kemper, J.S. Fuglestvedt, J.C. Fyfe, et al., 2021: Technical Summary Archived 21 July 2022 at the Wayback Machine. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 9 August 2021 at the Wayback Machine [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA (value taken from Figure TS.11 (d) on page 75)
  131. ^ "Ocean Acidification". National Geographic. April 27, 2017. Archived from the original on October 9, 2018. Retrieved October 9, 2018.
  132. ^ Terhaar, Jens; Frölicher, Thomas L.; Joos, Fortunat (2023). "Ocean acidification in emission-driven temperature stabilization scenarios: the role of TCRE and non-CO2 greenhouse gases". Environmental Research Letters. 18 (2): 024033. Bibcode:2023ERL....18b4033T. doi:10.1088/1748-9326/acaf91. ISSN 1748-9326. S2CID 255431338.
  133. ^ a b Doney, Scott C.; Busch, D. Shallin; Cooley, Sarah R.; Kroeker, Kristy J. (October 17, 2020). "The Impacts of Ocean Acidification on Marine Ecosystems and Reliant Human Communities". Annual Review of Environment and Resources. 45 (1): 83–112. doi:10.1146/annurev-environ-012320-083019. S2CID 225741986. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  134. ^ a b Emerson, Steven; Hedges, John (2008). "Chapter 4: Carbonate chemistry". Chemical Oceanography and the Marine Carbon Cycle (1 ed.). Cambridge University Press. doi:10.1017/cbo9780511793202. ISBN 978-0-521-83313-4.
  135. ^ Zeebe, R. E. and Wolf-Gladrow, D. (2001) CO2 in seawater: equilibrium, kinetics, isotopes, Elsevier Science B.V., Amsterdam, Netherlands ISBN 0-444-50946-1
  136. ^ Stumm, W, Morgan, J. J. (1981) Aquatic Chemistry, An Introduction Emphasizing Chemical Equilibria in Natural Waters. John Wiley & Sons. pp. 414–416. ISBN 0471048313.
  137. ^ IPCC, 2021: Annex VII: Glossary Archived 5 June 2022 at the Wayback Machine [Matthews, J.B.R., V. Möller, R. van Diemen, J.S. Fuglestvedt, V. Masson-Delmotte, C.  Méndez, S. Semenov, A. Reisinger (eds.)]. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 9 August 2021 at the Wayback Machine [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA
  138. ^ "Calculation of residence times in seawater of some important solutes" (PDF). gly.uga.edu. Archived from the original (PDF) on November 23, 2018. Retrieved February 3, 2014.
  139. ^ Chester, R.; Jickells, Tim (2012). "Chapter 11: Trace elements in the oceans". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. ISBN 978-1-118-34909-0. OCLC 781078031.
  140. ^ "Monterey Bay Aquarium Research Institute".
  141. ^ "Monterey Bay Aquarium Research Institute".
  142. ^ "Potassium". www3.mbari.org.
  143. ^ Paytan, Adina; McLaughlin, Karen (2007). "The Oceanic Phosphorus Cycle". Chemical Reviews. 107 (2): 563–576. doi:10.1021/cr0503613. ISSN 0009-2665. PMID 17256993. S2CID 1872341.
  144. ^ Cordell, Dana; Drangert, Jan-Olof; White, Stuart (2009). "The story of phosphorus: Global food security and food for thought". Global Environmental Change. 19 (2): 292–305. Bibcode:2009GEC....19..292C. doi:10.1016/j.gloenvcha.2008.10.009. S2CID 1450932.
  145. ^ Edixhoven, J. D.; Gupta, J.; Savenije, H. H. G. (December 19, 2014). "Recent revisions of phosphate rock reserves and resources: a critique". Earth System Dynamics. 5 (2): 491–507. Bibcode:2014ESD.....5..491E. doi:10.5194/esd-5-491-2014. ISSN 2190-4987. S2CID 858311.
  146. ^ Amundson, R.; Berhe, A. A.; Hopmans, J. W.; Olson, C.; Sztein, A. E.; Sparks, D. L. (2015). "Soil and human security in the 21st century". Science. 348 (6235): 1261071. Bibcode:2015Sci...34861071A. doi:10.1126/science.1261071. ISSN 0036-8075. PMID 25954014. S2CID 206562728.
  147. ^ Apprill, A. (2017)"Marine animal microbiomes: toward understanding host–microbiome interactions in a changing ocean". Frontiers in Marine Science, 4: 222. doi:10.3389/fmars.2017.00222. Material was copied from this source, which is available under a Creative Commons Attribution 4.0 International License.
  148. ^ "Chapter 34: The Biosphere: An Introduction to Earth's Diverse Environment". Biology: Concepts & Connections. section 34.7. Archived from the original on July 13, 2018. Retrieved May 14, 2014.
  149. ^ a b Cavicchioli R, Ripple WJ, Timmis KN, Azam F, Bakken LR, Baylis M, et al. (September 2019). "Scientists' warning to humanity: microorganisms and climate change". Nature Reviews. Microbiology. 17 (9): 569–586. doi:10.1038/s41579-019-0222-5. PMC 7136171. PMID 31213707. Modified text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License.
  150. ^ Drogin, B (August 2, 2009). "Mapping an ocean of species". Los Angeles Times. Retrieved August 18, 2009.
  151. ^ Bouchet, Philippe; Decock, Wim; Lonneville, Britt; Vanhoorne, Bart; Vandepitte, Leen (June 2023). "Marine biodiversity discovery: the metrics of new species descriptions". Frontiers in Marine Science. 10 (3389). doi:10.3389/fmars.2023.929989 – via ResearchGate.
  152. ^ Paul, GS (2010). "The Evolution of Dinosaurs and their World". The Princeton Field Guide to Dinosaurs. Princeton: Princeton University Press. p. 19. ISBN 978-0-691-13720-9.
  153. ^ Bortolotti, Dan (2008). Wild blue: a natural history of the world's largest animal. New York: Thomas Dunn Books. ISBN 978-0-312-38387-9. OCLC 213451450.
  154. ^ Bar-On YM, Phillips R, Milo R (June 2018). "The biomass distribution on Earth". Proceedings of the National Academy of Sciences of the United States of America. 115 (25): 6506–6511. Bibcode:2018PNAS..115.6506B. doi:10.1073/pnas.1711842115. PMC 6016768. PMID 29784790.
  155. ^ "Census Of Marine Life". Smithsonian. April 30, 2018. Retrieved October 29, 2020.
  156. ^ Abercrombie, M., Hickman, C.J. and Johnson, M.L. 1966.A Dictionary of Biology. Penguin Reference Books, London
  157. ^ "Oceanic Institute". www.oceanicinstitute.org. Archived from the original on January 3, 2019. Retrieved December 1, 2018.
  158. ^ "Ocean Habitats and Information". January 5, 2017. Archived from the original on April 1, 2017. Retrieved December 1, 2018.
  159. ^ "Facts and figures on marine biodiversity | United Nations Educational, Scientific and Cultural Organization". www.unesco.org. Retrieved December 1, 2018.
  160. ^ United States Environmental Protection Agency (March 2, 2006). "Marine Ecosystems". Retrieved August 25, 2006.
  161. ^ Zacharias, Mark (2014). Marine Policy: An Introduction to Governance and International Law of the Oceans. Routledge. ISBN 978-1136212475.
  162. ^ Halpern, Benjamin S.; Walbridge, Shaun; Selkoe, Kimberly A.; Kappel, Carrie V.; Micheli, Fiorenza; D'Agrosa, Caterina; Bruno, John F.; Casey, Kenneth S.; Ebert, Colin; Fox, Helen E.; Fujita, Rod (2008). "A Global Map of Human Impact on Marine Ecosystems". Science. 319 (5865): 948–952. Bibcode:2008Sci...319..948H. doi:10.1126/science.1149345. ISSN 0036-8075. PMID 18276889. S2CID 26206024.
  163. ^ Sauerbier, Charles L.; Meurn, Robert J. (2004). Marine Cargo Operations: a guide to stowage. Cambridge, Md: Cornell Maritime Press. pp. 1–16. ISBN 978-0-87033-550-1.
  164. ^ "Industry Globalization | World Shipping Council". www.worldshipping.org. Archived from the original on January 27, 2021. Retrieved May 4, 2021.
  165. ^ a b c The State of World Fisheries and Aquaculture 2020. FAO. 2020. doi:10.4060/ca9229en. hdl:10535/3776. ISBN 978-92-5-132692-3. S2CID 242949831.
  166. ^ "Fisheries: Latest data". GreenFacts. Retrieved April 23, 2013.
  167. ^ a b "What is Ocean Energy". Ocean Energy Systems. 2014. Retrieved May 14, 2021.
  168. ^ Cruz, João (2008). Ocean Wave Energy – Current Status and Future Perspectives. Springer. p. 2. ISBN 978-3-540-74894-6.
  169. ^ "Offshore Wind Power 2010". BTM Consult. 22 November 2010. Archived from the original on 30 June 2011. Retrieved 25 April 2013.
  170. ^ Lamb, Robert (2011). "How offshore drilling works". HowStuffWorks. Retrieved May 6, 2013.
  171. ^ a b "The United Nations Convention on the Law of the Sea (A historical perspective)". United Nations Division for Ocean Affairs and the Law of the Sea. Retrieved May 8, 2013.
  172. ^ Evans, J. P. (2011). Environmental Governance. Hoboken: Taylor & Francis. ISBN 978-0-203-15567-7. OCLC 798531922.
  173. ^ Halpern, B.S.; Frazier, M.; Afflerbach, J.; et al. (2019). "Recent pace of change in human impact on the world's ocean". Scientific Reports. 9 (1): 11609. Bibcode:2019NatSR...911609H. doi:10.1038/s41598-019-47201-9. PMC 6691109. PMID 31406130.
  174. ^ Cheng, Lijing; Abraham, John; Hausfather, Zeke; Trenberth, Kevin E. (January 11, 2019). "How fast are the oceans warming?". Science. 363 (6423): 128–129. Bibcode:2019Sci...363..128C. doi:10.1126/science.aav7619. PMID 30630919. S2CID 57825894.
  175. ^ a b Doney, Scott C.; Busch, D. Shallin; Cooley, Sarah R.; Kroeker, Kristy J. (October 17, 2020). "The Impacts of Ocean Acidification on Marine Ecosystems and Reliant Human Communities". Annual Review of Environment and Resources. 45 (1): 83–112. doi:10.1146/annurev-environ-012320-083019. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License Archived 2017-10-16 at the Wayback Machine
  176. ^ a b Bindoff, N.L., W.W.L. Cheung, J.G. Kairo, J. Arístegui, V.A. Guinder, R. Hallberg, N. Hilmi, N. Jiao, M.S. Karim, L. Levin, S. O'Donoghue, S.R. Purca Cuicapusa, B. Rinkevich, T. Suga, A. Tagliabue, and P. Williamson, 2019: Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities Archived 2019-12-20 at the Wayback Machine. In: IPCC Special Report on the Ocean and Cryosphere in a Changing Climate Archived 2021-07-12 at the Wayback Machine [H.-O. Pörtner, D.C. Roberts, V. Masson-Delmotte, P. Zhai, M. Tignor, E. Poloczanska, K. Mintenbeck, A. Alegría, M. Nicolai, A. Okem, J. Petzold, B. Rama, N.M. Weyer (eds.)]. In press.
  177. ^ Freedman, Andrew (September 29, 2020). "Mixing of the planet's ocean waters is slowing down, speeding up global warming, study finds". The Washington Post. Archived from the original on October 15, 2020. Retrieved October 12, 2020.
  178. ^ Cheng, Lijing; Trenberth, Kevin E.; Gruber, Nicolas; Abraham, John P.; Fasullo, John T.; Li, Guancheng; Mann, Michael E.; Zhao, Xuanming; Zhu, Jiang (2020). "Improved Estimates of Changes in Upper Ocean Salinity and the Hydrological Cycle". Journal of Climate. 33 (23): 10357–10381. Bibcode:2020JCli...3310357C. doi:10.1175/jcli-d-20-0366.1.
  179. ^ Chester, R.; Jickells, Tim (2012). "Chapter 9: Nutrients oxygen organic carbon and the carbon cycle in seawater". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. pp. 182–183. ISBN 978-1-118-34909-0. OCLC 781078031. Archived from the original on February 18, 2022. Retrieved October 20, 2022.
  180. ^ Sheppard, Charles, ed. (2019). World seas: an Environmental Evaluation. Vol. III, Ecological Issues and Environmental Impacts (Second ed.). London: Academic Press. ISBN 978-0-12-805204-4. OCLC 1052566532.
  181. ^ "Marine Pollution". Education | National Geographic Society. Retrieved June 19, 2023.
  182. ^ Duce, Robert; Galloway, J.; Liss, P. (2009). "The Impacts of Atmospheric Deposition to the Ocean on Marine Ecosystems and Climate WMO Bulletin Vol 58 (1)". Archived from the original on December 18, 2023. Retrieved September 22, 2020.
  183. ^ "What is the biggest source of pollution in the ocean?". National Ocean Service (US). Silver Spring, MD: National Oceanic and Atmospheric Administration. Retrieved September 21, 2022.
  184. ^ Breitburg, Denise; Levin, Lisa A.; Oschlies, Andreas; Grégoire, Marilaure; Chavez, Francisco P.; Conley, Daniel J.; Garçon, Véronique; Gilbert, Denis; Gutiérrez, Dimitri; Isensee, Kirsten; Jacinto, Gil S. (January 5, 2018). "Declining oxygen in the global ocean and coastal waters". Science. 359 (6371): eaam7240. Bibcode:2018Sci...359M7240B. doi:10.1126/science.aam7240. ISSN 0036-8075. PMID 29301986.
  185. ^ Scales, Helen (March 29, 2007). "Shark Declines Threaten Shellfish Stocks, Study Says". National Geographic News. Archived from the original on November 6, 2007. Retrieved May 1, 2012.
  186. ^ The State of World Fisheries and Aquaculture 2024. FAO. June 7, 2024. doi:10.4060/cd0683en. ISBN 978-92-5-138763-4.
  187. ^ "Protecting the Marine Environment". www.epa.gov. March 26, 2014. Retrieved October 25, 2021.
  188. ^ "Quantitative targets for marine protection: a review of the scientific basis and applications" (PDF). Retrieved October 25, 2021.
  189. ^ Farran, Sue. "Is marine protection compatible with the right to economic development in Pacific Island States?".
  190. ^ Manson, Paul; Nielsen-Pincus, Max; Granek, Elise F.; Swearingen, Thomas C. (February 15, 2021). "Public perceptions of ocean health and marine protection: Drivers of support for Oregon's marine reserves". Ocean & Coastal Management. 201: 105480. Bibcode:2021OCM...20105480M. doi:10.1016/j.ocecoaman.2020.105480. ISSN 0964-5691. S2CID 230555294.
  191. ^ Dinerstein, E.; Vynne, C.; Sala, E.; Joshi, A. R.; Fernando, S.; Lovejoy, T. E.; Mayorga, J.; Olson, D.; Asner, G. P.; Baillie, J. E. M.; Burgess, N. D.; Burkart, K.; Noss, R. F.; Zhang, Y. P.; Baccini, A.; Birch, T.; Hahn, N.; Joppa, L. N.; Wikramanayake, E. (2019). "A Global Deal For Nature: Guiding principles, milestones, and targets". Science Advances. 5 (4): eaaw2869. Bibcode:2019SciA....5.2869D. doi:10.1126/sciadv.aaw2869. PMC 6474764. PMID 31016243.
  192. ^ "Improving ocean protection with the first marine protected areas guide". Institut de Recherche pour le Développement. Retrieved October 19, 2021.
  193. ^ Grorud-Colvert, Kirsten; Sullivan-Stack, Jenna; Roberts, Callum; Constant, Vanessa; Horta e Costa, Barbara; Pike, Elizabeth P.; Kingston, Naomi; Laffoley, Dan; Sala, Enric; Claudet, Joachim; Friedlander, Alan M.; Gill, David A.; Lester, Sarah E.; Day, Jon C.; Gonçalves, Emanuel J.; Ahmadia, Gabby N.; Rand, Matt; Villagomez, Angelo; Ban, Natalie C.; Gurney, Georgina G.; Spalding, Ana K.; Bennett, Nathan J.; Briggs, Johnny; Morgan, Lance E.; Moffitt, Russell; Deguignet, Marine; Pikitch, Ellen K.; Darling, Emily S.; Jessen, Sabine; Hameed, Sarah O.; Di Carlo, Giuseppe; Guidetti, Paolo; Harris, Jean M.; Torre, Jorge; Kizilkaya, Zafer; Agardy, Tundi; Cury, Philippe; Shah, Nirmal J.; Sack, Karen; Cao, Ling; Fernandez, Miriam; Lubchenco, Jane (2021). "The MPA Guide: A framework to achieve global goals for the ocean" (PDF). Science. 373 (6560): eabf0861. doi:10.1126/science.abf0861. PMID 34516798. S2CID 237473020.
  194. ^ Kim, Juliana; Treisman, Rachel. "What to know about the new U.N. high seas treaty – and the next steps for the accord". NPR. Retrieved March 9, 2023.
  195. ^ Flores, Gaby. "How people power helped protect the oceans". Greenpeace. Retrieved March 9, 2023.
  196. ^ Hemingway Jaynes, Cristen (June 20, 2023). "Newly Adopted UN High Seas Treaty Gives Ocean a 'Fighting Chance'". Ecowatch. Retrieved June 23, 2023.