Misplaced Pages

Ocean gyre

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Subtropical gyre) Any large system of circulating ocean surface currents For other uses, see Gyre (disambiguation). 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. World map of the five major ocean gyres

In oceanography, a gyre (/ˈdʒaɪər/) is any large system of ocean surface currents moving in a circular fashion driven by wind movements. Gyres are caused by the Coriolis effect; planetary vorticity, horizontal friction and vertical friction determine the circulatory patterns from the wind stress curl (torque).

Gyre can refer to any type of vortex in an atmosphere or a sea, even one that is human-created, but it is most commonly used in terrestrial oceanography to refer to the major ocean systems.

Gyre formation

The largest ocean gyres are wind-driven, meaning that their locations and dynamics are controlled by the prevailing global wind patterns: easterlies at the tropics and westerlies at the midlatitudes. These wind patterns result in a wind stress curl that drives Ekman pumping in the subtropics (resulting in downwelling) and Ekman suction in subpolar regions (resulting in upwelling). Ekman pumping results in an increased sea surface height at the center of the gyre and anticyclonic geostrophic currents in subtropical gyres. Ekman suction results in a depressed sea surface height and cyclonic geostrophic currents in subpolar gyres.

Wind-driven ocean gyres are asymmetrical, with stronger flows on their western boundary and weaker flows throughout their interior. The weak interior flow that is typical over most of the gyre is a result of the conservation of potential vorticity. In the shallow water equations (applicable for basin-scale flow as the horizontal length scale is much greater than the vertical length scale), potential vorticity is a function of relative (local) vorticity ζ {\displaystyle \zeta } (zeta), planetary vorticity f {\displaystyle f} , and the depth H {\displaystyle H} , and is conserved with respect to the material derivative:

D D t ( ζ + f H ) = 0 {\displaystyle {D \over Dt}\left({\frac {\zeta +f}{H}}\right)=0}

In the case of the subtropical ocean gyre, Ekman pumping results in water piling up in the center of the gyre, compressing water parcels. This results in a decrease in H {\displaystyle H} , so by the conservation of potential vorticity the numerator ζ + f {\displaystyle \zeta +f} must also decrease. It can be further simplified by realizing that, in basin-scale ocean gyres, the relative vorticity ζ {\displaystyle \zeta } is small, meaning that local changes in vorticity cannot account for the decrease in H {\displaystyle H} . Thus, the water parcel must change its planetary vorticity f {\displaystyle f} accordingly. The only way to decrease the planetary vorticity is by moving the water parcel equatorward, so throughout the majority of subtropical gyres there is a weak equatorward flow. Harald Sverdrup quantified this phenomenon in his 1947 paper, "Wind Driven Currents in a Baroclinic Ocean", in which the (depth-integrated) Sverdrup balance is defined as:

f V g = β ρ w E {\displaystyle fV_{g}=\beta \rho w_{E}}

Here, V g {\displaystyle V_{g}} is the meridional mass transport (positive north), β {\displaystyle \beta } is the Rossby parameter, ρ {\displaystyle \rho } is the water density, and w E {\displaystyle w_{E}} is the vertical Ekman velocity due to wind stress curl (positive up). It can be clearly seen in this equation that for a negative Ekman velocity (e.g., Ekman pumping in subtropical gyres), meridional mass transport (Sverdrup transport) is negative (south, equatorward) in the northern hemisphere ( f > 0 {\displaystyle f>0} ). Conversely, for a positive Ekman velocity (e.g., Ekman suction in subpolar gyres), Sverdrup transport is positive (north, poleward) in the northern hemisphere.

Two plots of velocity profile, the top of which depicts the flow velocity with a positive slope near the western boundary and the bottom of which depicts the flow velocity with a negative slope near the eastern boundary.
The velocity profile within the boundary layer calculated using Munk's boundary layer solution for both the case of a western boundary (top) and eastern boundary (bottom) in a northern hemisphere subtropical gyre. Note that positive vorticity is input into the flow near the boundary only in the case of the western boundary current, meaning this is the only valid solution to gyre return flow.

Western intensification

See also: Boundary current § Western intensification

As the Sverdrup balance argues, subtropical ocean gyres have a weak equatorward flow and subpolar ocean gyres have a weak poleward flow over most of their area. However, there must be some return flow that goes against the Sverdrup transport in order to preserve mass balance. In this respect, the Sverdrup solution is incomplete, as it has no mechanism in which to predict this return flow. Contributions by both Henry Stommel and Walter Munk resolved this issue by showing that the return flow of gyres is done through an intensified western boundary current. Stommel's solution relies on a frictional bottom boundary layer which is not necessarily physical in a stratified ocean (currents do not always extend to the bottom).

Two plots: the left one showing a sinusoidal function that represents the winds over a subtropical gyre and the right one showing the resulting gyre circulation in a rectangular basin, which is clockwise around the basin and intensified to the west.
The normalized stream function ψ {\displaystyle \psi } (right) computed using Munk's boundary layer solution in a rectangular, flat-bottomed ocean gyre on a beta plane in the northern hemisphere centered at 30°N with horizontal length scale L {\displaystyle L} . The applied winds τ {\displaystyle \tau } (left) are sinusoidal, which is an approximation of the typical winds driving a subtropical gyre. Flow is along streamlines (black dotted lines) and the stream function is negative throughout the gyre, indicating the gyre is rotating clockwise. The distance between streamlines is inversely proportional to the flow speed – note the much closer streamlines on the west side of the basin, indicating western intensification of the gyre.

Munk's solution instead relies on friction between the return flow and the sidewall of the basin. This allows for two cases: one with the return flow on the western boundary (western boundary current) and one with the return flow on the eastern boundary (eastern boundary current). A qualitative argument for the presence of western boundary current solutions over eastern boundary current solutions can be found again through the conservation of potential vorticity. Considering again the case of a subtropical northern hemisphere gyre, the return flow must be northward. In order to move northward (an increase in planetary vorticity f {\displaystyle f} ), there must be a source of positive relative vorticity to the system. The relative vorticity in the shallow-water system is:

ζ = v x u y {\displaystyle \zeta ={\partial v \over \partial x}-{\partial u \over \partial y}}

Here v {\displaystyle v} is again the meridional velocity and u {\displaystyle u} is the zonal velocity. In the sense of a northward return flow, the zonal component is neglected and only the meridional velocity is important for relative vorticity. Thus, this solution requires that v / x > 0 {\displaystyle \partial v/\partial x>0} in order to increase the relative vorticity and have a valid northward return flow in the northern hemisphere subtropical gyre.

Due to friction at the boundary, the velocity of flow must go to zero at the sidewall before reaching some maximum northward velocity within the boundary layer and decaying to the southward Sverdrup transport solution far away from the boundary. Thus, the condition that v / x > 0 {\displaystyle \partial v/\partial x>0} can only be satisfied through a western boundary frictional layer, as the eastern boundary frictional layer forces v / x < 0 {\displaystyle \partial v/\partial x<0} . One can make similar arguments for subtropical gyres in the southern hemisphere and for subpolar gyres in either hemisphere and see that the result remains the same: the return flow of an ocean gyre is always in the form of a western boundary current.

The western boundary current must transport on the same order of water as the interior Sverdrup transport in a much smaller area. This means western boundary currents are much stronger than interior currents, a phenomenon called "western intensification".

Gyre distribution

Subtropical gyres

There are five major subtropical gyres across the world's oceans: the North Atlantic Gyre, the South Atlantic Gyre, the Indian Ocean Gyre, the North Pacific Gyre, and the South Pacific Gyre. All subtropical gyres are anticyclonic, meaning that in the northern hemisphere they rotate clockwise, while the gyres in the southern hemisphere rotate counterclockwise. This is due to the Coriolis force. Subtropical gyres typically consist of four currents: a westward flowing equatorial current, a poleward flowing, narrow, and strong western boundary current, an eastward flowing current in the midlatitudes, and an equatorward flowing, weaker, and broader eastern boundary current.

North Atlantic Gyre

The North Atlantic Gyre is located in the northern hemisphere in the Atlantic Ocean, between the Intertropical Convergence Zone (ITCZ) in the south and Iceland in the north. The North Equatorial Current brings warm waters west towards the Caribbean and defines the southern edge of the North Atlantic Gyre. Once these waters reach the Caribbean they join the warm waters in the Gulf of Mexico and form the Gulf Stream, a western boundary current. This current then heads north and east towards Europe, forming the North Atlantic Current. The Canary Current flows south along the western coast of Europe and north Africa, completing the gyre circulation. The center of the gyre is the Sargasso Sea, which is characterized by the dense accumulation of Sargassum seaweed.

South Atlantic Gyre

The South Atlantic Gyre is located in the southern hemisphere in the Atlantic Ocean, between the Intertropical Convergence Zone in the north and the Antarctic Circumpolar Current to the south. The South Equatorial Current brings water west towards South America, forming the northern boundary of the South Atlantic gyre. Here, the water moves south in the Brazil Current, the western boundary current of the South Atlantic Gyre. The Antarctic Circumpolar Current forms both the southern boundary of the gyre and the eastward component of the gyre circulation. Eventually, the water reaches the west coast of Africa, where it is brought north along the coast as a part of the eastern boundary Benguela Current, completing the gyre circulation. The Benguela Current experiences the Benguela Niño event, an Atlantic Ocean analogue to the Pacific Ocean's El Niño, and is correlated with a reduction in primary productivity in the Benguela upwelling zone.

Indian Ocean Gyre

The Indian Ocean Gyre, located in the Indian Ocean, is, like the South Atlantic Gyre, bordered by the Intertropical Convergence Zone in the north and the Antarctic Circumpolar Current to the south. The South Equatorial Current forms the northern boundary of the Indian Ocean Gyre as it flows west along the equator towards the east coast of Africa. At the coast of Africa, the South Equatorial Current is split by Madagascar into the Mozambique Current, flowing south through the Mozambique Channel, and the East Madagascar Current, flowing south along the east coast of Madagascar, both of which are western boundary currents. South of Madagascar the two currents join to form the Agulhas Current. The Agulhas Current flows south until it joins the Antarctic Circumpolar Current, which flows east at the southern edge of the Indian Ocean Gyre. Due to the African continent not extending as far south as the Indian Ocean Gyre, some of the water in the Agulhas Current "leaks" into the Atlantic Ocean, with potentially important effects for global thermohaline circulation. The gyre circulation is completed by the north flowing West Australian Current, which forms the eastern boundary of the gyre.

North Pacific Gyre

The North Pacific Gyre, one of the largest ecosystems on Earth, is bordered to the south by the Intertropical Convergence Zone and extending north to roughly 50°N. At the southern boundary of the North Pacific Gyre, the North Equatorial Current flows west along the equator towards southeast Asia. The Kuroshio Current is the western boundary current of the North Pacific Gyre, flowing northeast along the coast of Japan. At roughly 50°N, the flow turns east and becomes the North Pacific Current. The North Pacific Current flows east, eventually bifurcating near the west coast of North America into the northward flowing Alaska Current and the southward flowing California Current. The Alaska Current is the eastern boundary current of the subpolar Alaska Gyre, while the California Current is the eastern boundary current that completes the North Pacific Gyre circulation. Within the North Pacific Gyre is the Great Pacific Garbage Patch, an area of increased plastic waste concentration.

South Pacific Gyre

The South Pacific Gyre, like its northern counterpart, is one of the largest ecosystems on Earth with an area that accounts for around 10% of the global ocean surface area. Within this massive area is Point Nemo, the location on Earth that is farthest away from all continental landmass (2,688 km away from the closest land). The remoteness of this gyre complicates sampling, causing this gyre to be historically under sampled in oceanographic datasets. At the northern boundary of the South Pacific Gyre, the South Equatorial Current flows west towards southeast Asia and Australia. There, it turns south as it flows in the East Australian Current, a western boundary current. The Antarctic Circumpolar Current again returns the water to the east. The flow turns north along the western coast of South America in the Humboldt Current, the eastern boundary current that completes the South Pacific Gyre circulation. Like the North Pacific Gyre, the South Pacific Gyre has an elevated concentration of plastic waste near the center, termed the South Pacific garbage patch. Unlike the North Pacific garbage patch which was first described in 1988, the South Pacific garbage patch was discovered much more recently in 2016 (a testament to the extreme remoteness of the South Pacific Gyre).

Subpolar gyres

Subpolar gyres form at high latitudes (around 60°). Circulation of surface wind and ocean water is cyclonic, counterclockwise in the northern hemisphere and clockwise in the southern hemisphere, around a low-pressure area, such as the persistent Aleutian Low and the Icelandic Low. The wind stress curl in this region drives the Ekman suction, which creates an upwelling of nutrient-rich water from the lower depths.

Subpolar circulation in the southern hemisphere is dominated by the Antarctic Circumpolar Current, due to the lack of large landmasses breaking up the Southern Ocean. There are minor gyres in the Weddell Sea and the Ross Sea, the Weddell Gyre and Ross Gyre, which circulate in a clockwise direction.

North Atlantic Subpolar Gyre

The distribution of the North Atlantic Subpolar Gyre shown above the North Atlantic Gyre to the South.

The North Atlantic Subpolar Gyre, located in the North Atlantic Ocean, is characterized by a counterclockwise rotation of surface waters. It plays a crucial role in the global oceanic conveyor belt system, influencing climate and marine ecosystems. The gyre is driven by the convergence of warm, salty waters from the south and cold, fresher waters from the north. As these waters meet, the warm, dense water sinks beneath the lighter, colder water, initiating a complex circulation pattern. The North Atlantic Subpolar Gyre has significant implications for climate regulation, as it helps redistribute heat and nutrients throughout the North Atlantic, influencing weather patterns and supporting diverse marine life. Additionally, changes in the gyre's strength and circulation can impact regional climate variability and may be influenced by broader climate change trends.

The Atlantic Meridional Overturning Circulation (AMOC) is a key component of the global climate system through its transport of heat and freshwater. The North Atlantic Subpolar Gyre is in a region where the AMOC is actively developed and shaped through mixing and water mass transformation. It is a region where large amounts of heat transported northward by the ocean are released into the atmosphere, thereby modifying the climate of northwest Europe. The North Atlantic Subpolar Gyre has a complex topography with a series of basins in which the large-scale circulation is characterized by cyclonic boundary currents and interior recirculation. The North Atlantic Current develops out of the Gulf Stream extension and turns eastward, crossing the Atlantic in a wide band between about 45°N and 55°N creating the southern border of the North Atlantic Subpolar Gyre. There are several branches of the North Atlantic Current, and they flow into an eastern intergyral region in the Bay of Biscay, the Rockall Trough, the Iceland Basin, and the Irminger Sea. Part of the North Atlantic Current flows into the Norwegian Sea, and some recirculate within the boundary currents of the subpolar gyre.

Ross Gyre

The Ross Gyre is located in the Southern Ocean surrounding Antarctica, just outside of the Ross Sea. This gyre is characterized by a clockwise rotation of surface waters, driven by the combined influence of wind, the Earth's rotation, and the shape of the seafloor. The gyre plays a crucial role in the transport of heat, nutrients, and marine life in the Southern Ocean, affecting the distribution of sea ice and influencing regional climate patterns.

The Ross Sea, Antarctica, is a region where the mixing of distinct water masses and complex interactions with the cryosphere lead to the production and export of dense water, with global-scale impacts. which controls the proximity of the warm waters of the Antarctic Circumpolar Current to the Ross Sea continental shelf, where they may drive ice shelf melting and increase sea level. The deepening of sea level pressures over the Southeast Pacific/Amundsen-Bellingshausen Seas generates a cyclonic circulation cell that reduces sea surface heights north of the Ross Gyre via Ekman suction. The relative reduction of sea surface heights to the north facilitates a northeastward expansion of the outer boundary of the Ross Gyre. Further, the gyre is intensified by a westward ocean stress anomaly over its southern boundary. The ensuing southward Ekman transport anomaly raises sea surface heights over the continental shelf and accelerates the westward throughflow by increasing the cross-slope pressure gradient. The sea level pressure center may have a greater impact on the Ross Gyre transport or the throughflow, depending on its location and strength. This gyre has significant effects on interactions in the Southern Ocean between waters of the Antarctic margin, the Antarctic Circumpolar Current, and intervening gyres with a strong seasonal sea ice cover play a major role in the climate system.

The Ross Sea is the southernmost sea on Earth and holds the United States' McMurdo Station and Italian Zuchelli Station. Even though this gyre is located nearby two of the most prominent research stations in the world for Antarctic study, the Ross Gyre remains one of the least sampled gyres in the world.

Locations of the Weddell & Ross Gyre's and their distribution in the Southern Ocean.

Weddell Gyre

The Weddell Gyre is located in the Southern Ocean surrounding Antarctica, just outside of the Weddell Sea. It is characterized by a clockwise rotation of surface waters, influenced by the combined effects of winds, the Earth's rotation, and the seafloor's topography. Like the Ross Gyre, the Weddell Gyre plays a critical role in the movement of heat, nutrients, and marine life in the Southern Ocean. Insights into the behavior and variability of the Weddell Gyre are crucial for comprehending the interaction between ocean processes in the southern hemisphere and their implications for the global climate system.

This gyre is formed by interactions between the Antarctic Circumpolar Current and the Antarctic Continental Shelf. The Weddell Gyre (WG) is one of the main oceanographic features of the Southern Ocean south of the Antarctic Circumpolar Current which plays an influential role in global ocean circulation as well as gas exchange with the atmosphere. The WG is situated in the Atlantic sector of the Southern Ocean, south of 55–60°S and roughly between 60°W and 30°E (Deacon, 1979). It stretches over the Weddell abyssal plain, where the Weddell Sea is situated, and extends east into the Enderby abyssal plain.

Beaufort Sea Gyre

Image of the distribution of the Beaufort Sea Gyre and its relationship with the transpolar drift

The anti-cyclonic Beaufort Gyre is the dominant circulation of the Canada Basin and the largest freshwater reservoir in the Arctic Ocean's western and northern sectors. The Gyre is characterized by a large-scale, quasi-permanent, counterclockwise rotation of surface waters within the Beaufort Sea. This gyre functions as a critical mechanism for the transport of heat, nutrients, and sea ice within the Arctic region, thus influencing the physical and biological characteristics of the marine environment. Negative wind stress curl over the region, mediated by the sea ice pack, leads to Ekman pumping, downwelling of isopycnal surfaces, and storage of ~20,000 km3 of freshwater in the upper few hundred meters of the ocean. The gyre gains energy from winds in the south and loses energy in the north over a mean annual cycle. The strong atmospheric circulation in the autumn, combined with significant areas of open water, demonstrates the effect that wind stress has directly on the surface geostrophic currents. The Beaufort Gyre and the Transpolar Drift are interconnected due to their relationship in their role in transporting sea ice across the Arctic Ocean. Their influence on the distribution of freshwater has broad impacts for global sea level rise and climate dynamics.

Biogeochemistry of Gyres

An animation of a year in organism density on Earth. The South Pacific Gyre is visibly low (purple) in organism density.

Depending on their location around the world, gyres can be regions of high biological productivity or low productivity. Each gyre has a unique ecological profile but can be grouped by region due to dominating characteristics. Generally, productivity is greater for cyclonic gyres (e.g., subpolar gyres) that drive upwelling through Ekman suction and lesser for anticyclonic gyres (e.g., subtropical gyres) that drive downwelling through Ekman pumping, but this can differ between seasons and regions.

Subtropical gyres are sometimes described as "ocean deserts" or "biological deserts", in reference to arid land deserts where little life exists. Due to their oligotrophic characteristics, warm subtropical gyres have some of the least productive waters per unit surface area in the ocean. The downwelling of water that occurs in subtropical gyres takes nutrients deeper in the ocean, removing them from surface waters. Organic particles can also be removed from surface waters through gravitational sinking, where the particle is too heavy to remain suspended in the water column. However, since subtropical gyres cover 60% of the ocean surface, their relatively low production per unit area is made up for by covering massive areas of the Earth. This means that, despite being areas of relatively low productivity and low nutrients, they play a large role in contributing to the overall amount of ocean production.

In contrast to subtropical gyres, subpolar gyres can have a lot of biological activity due to Ekman suction upwelling driven by wind stress curl. Subpolar gyres in the North Atlantic have a "bloom and crash" pattern following seasonal and storm patterns. The highest productivity in the North Atlantic occurs in boreal spring when there are long days and high levels of nutrients. This is different to the subpolar North Pacific, where almost no phytoplankton bloom occurs and patterns of respiration are more consistent through time than in the North Atlantic.

Nutrient availability

The distribution of nitrate throughout the global ocean.

Primary production in the ocean is heavily dependent on the presence of nutrients and the availability of sunlight. Here, nutrients refers to nitrogen, nitrate, phosphate, and silicate, all important nutrients in biogeochemical processes that take place in the ocean. A commonly accepted method for relating different nutrient availabilities to each other in order to describe chemical processes is the Redfield, Ketchum, and Richards (RKR) equation. This equation describes the process of photosynthesis and respiration and the ratios of the nutrients involved.

The RKR Equation for Photosynthesis and Respiration:

106 CO 2 + 16 HNO 3 + H 3 PO 4 + 122 H 2 O ( CH 2 O ) 106 ( NH 3 ) 16 H 3 PO 4 + 138 O 2 {\displaystyle {\ce {106CO2 +16HNO3 +H3PO4 +122H2O ->(CH2O)106(NH3)16H3PO4 +138O2}}}
This plot shows the relationship to nitrogen and phosphorus availability throughout different areas of the global ocean. Nitrogen is most often more limiting than phosphorus for photosynthesis.

With the correct ratios of nutrients on the left side of the RKR equation and sunlight, photosynthesis takes place to produce plankton (primary production) and oxygen. Typically, the limiting nutrients to production are nitrogen and phosphorus with nitrogen being the most limiting.

Lack of nutrients in the surface waters of subtropical gyres is related to the strong downwelling and sinking of particles that occurs in these areas as mentioned earlier. However, nutrients are still present in these gyres. These nutrients can come from not only vertical transport, but also lateral transport across gyre fronts. This lateral transport helps make up for the large loss of nutrients due to downwelling and particle sinking. However, the major source of nitrate in the nitrate-limited subtropical gyres is a result of biological, not physical, factors. Nitrogen in subtropical gyres is produced primarily by nitrogen-fixing bacteria, which are common throughout most of the oligotrophic waters of subtropical gyres. These bacteria transform atmospheric nitrogen into bioavailable forms.

High-nutrient, low-chlorophyll regions

The Alaskan Gyre and Western Subarctic Gyre are an iron-limited environment rather than a nitrogen or phosphorus limited environment. This region relies on dust blowing off the state of Alaska and other landmasses nearby to supply iron. Because it is limited by iron instead of nitrogen or phosphorus, it is known as high-nutrient, low-chlorophyll region. Iron limitation in high-nutrient, low-chlorophyll regions results in water that is rich in other nutrients because they have not been removed by the small populations of plankton that live there.

Seasonality in the North Atlantic Subpolar Gyre

The North Atlantic Subpolar Gyre is an important part of the ocean's carbon dioxide drawdown mechanism. The photosynthesis of phytoplankton communities in this area seasonally depletes surface waters of carbon dioxide, removing it through primary production. This primary production occurs seasonally, with the highest amounts happening in summer. Generally, spring is an important time for photosynthesis as the light limitation imposed during winter is lifted and there are high levels of nutrients available. However, in the North Atlantic Subpolar Gyre, spring productivity is low in comparison to expected levels. It is hypothesized that this low productivity is because phytoplankton are less efficiently using light than they do in the summer months.

Trophic levels

Ocean gyres typically contain 5–6 trophic levels. The limiting factor for the number of trophic levels is the size of the phytoplankton, which are generally small in nutrient limited gyres. In low oxygen zones, oligotrophs are a large percentage of the phytoplankton.

At the intermediate level, small fishes and squid (especially ommastrephidae) dominate the nektonic biomass. They are important for the transport of energy from low trophic levels to high trophic levels. In some gyres, ommastrephidae are a major part of many animals' diets and can support the existence of large marine life.

Indigenous knowledge of ocean patterns

Indigenous Traditional Ecological Knowledge recognizes that Indigenous people, as the original caretakers, hold unique relationships with the land and waters. These relationships make TEK difficult to define, as Traditional Knowledge means something different to each person, each community, and each caretaker. The United Nations Declaration on the Rights of Indigenous Peoples begins by reminding readers that “respect for Indigenous knowledge, cultures and traditional practices contributes to sustainable and equitable development and proper management of the environment” Attempts to collect and store this knowledge have been made over the past twenty years. Conglomerates such as The Indigenous Knowledge Social Network (SIKU) https://siku.org/, the Igliniit project, and the Wales Inupiaq Sea Ice Directory have made strides in the inclusion and documentation of indigenous people's thoughts on global climate, oceanographic, and social trends.

One example involves ancient Polynesians and how they discovered and then travelled throughout the Pacific Ocean from modern day Polynesia to Hawaii and New Zealand. Known as wayfinding, navigators would use the stars, winds, and ocean currents to know where they were on the ocean and where they were headed. These navigators were intimately familiar with Pacific currents that create the North Pacific gyre and this way of navigating continues today.

Another example involves the Māori people who came from Polynesia and are an indigenous group in New Zealand. Their way of life and culture has strong connections to the ocean. The Māori believe that the sea is the source of all life and is an energy, called Tangaroa. This energy could manifest in many different ways, like strong ocean currents, calm seas, or turbulent storms. The Māori have a rich oral history of navigation within the Southern Ocean and Antarctic Ocean and a deep understanding their ice and ocean patterns. A current research project is aimed at consolidating these oral histories. Efforts are being made to integrate TEK with Western science in marine and ocean research in New Zealand. Additional research efforts aim to collate indigenous oral histories and incorporate indigenous knowledge into climate change adaptation practices in New Zealand that will directly affect the Māori and other indigenous communities.

Climate change

Ocean circulation re-distributes the heat and water-resources, therefore determines the regional climate. For example, the western branches of the subtropical gyres flow from the lower latitudes towards higher latitudes, bringing relatively warm and moist air to the adjacent land, contributing to a mild and wet climate (e.g., East China, Japan). In contrast, the eastern boundary currents of the subtropical gyres streaming from the higher latitudes towards lower latitudes, corresponding to a relatively cold and dry climate (e.g., California).

Currently, the core of the subtropical gyres are around 30° in both Hemispheres. However, their positions were not always there. Satellite observational sea surface height and sea surface temperature data suggest that the world's major ocean gyres are slowly moving towards higher latitudes in the past few decades. Such feature show agreement with climate model prediction under anthropogenic global warming. Paleo-climate reconstruction also suggest that during the past cold climate intervals, i.e., ice ages, some of the western boundary currents (western branches of the subtropical ocean gyres) are closer to the equator than their modern positions. These evidence implies that global warming is very likely to push the large-scale ocean gyres towards higher latitudes.

Pollution

This section is an excerpt from Garbage patch.
Trash washed ashore in Hawaii from the Great Pacific Garbage Patch

A garbage patch is a gyre of marine debris particles caused by the effects of ocean currents and increasing plastic pollution by human populations. These human-caused collections of plastic and other debris are responsible for ecosystem and environmental problems that affect marine life, contaminate oceans with toxic chemicals, and contribute to greenhouse gas emissions. Once waterborne, marine debris becomes mobile. Flotsam can be blown by the wind, or follow the flow of ocean currents, often ending up in the middle of oceanic gyres where currents are weakest.

Within garbage patches, the waste is not compact, and although most of it is near the surface of the ocean, it can be found up to more than 30 metres (100 ft) deep in the water. Patches contain plastics and debris in a range of sizes from Microplastics and small scale plastic pellet pollution, to large objects such as fishing nets and consumer goods and appliances lost from flood and shipping loss.

Garbage patches grow because of widespread loss of plastic from human trash collection systems. The United Nations Environmental Program estimated that "for every square mile of ocean" there are about "46,000 pieces of plastic". The 10 largest emitters of oceanic plastic pollution worldwide are, from the most to the least, China, Indonesia, Philippines, Vietnam, Sri Lanka, Thailand, Egypt, Malaysia, Nigeria, and Bangladesh, largely through the rivers Yangtze, Indus, Yellow, Hai, Nile, Ganges, Pearl, Amur, Niger, and the Mekong, and accounting for "90 percent of all the plastic that reaches the world's oceans". Asia was the leading source of mismanaged plastic waste, with China alone accounting for 2.4 million metric tons.

The best known of these is the Great Pacific Garbage Patch which has the highest density of marine debris and plastic. The Pacific Garbage patch has two mass buildups: the western garbage patch and the eastern garbage patch, the former off the coast of Japan and the latter between California and Hawaii. These garbage patches contain 90 million tonnes (100 million short tons) of debris. Other identified patches include the North Atlantic garbage patch between North America and Africa, the South Atlantic garbage patch located between eastern South America and the tip of Africa, the South Pacific garbage patch located west of South America, and the Indian Ocean garbage patch found east of South Africa listed in order of decreasing size.

See also

References

  1. Heinemann, B. and the Open University (1998) Ocean circulation, Oxford University Press: Page 98
  2. Lissauer, Jack J.; de Pater, Imke (2019). Fundamental Planetary Sciences : physics, chemistry, and habitability. New York: Cambridge University Press. ISBN 978-1108411981.
  3. ^ Talley, Lynne D.; Pickard, George L.; Emery, William J.; Swift, James H. (2011), "Introduction to Descriptive Physical Oceanography", Descriptive Physical Oceanography, Elsevier, pp. 142–145, doi:10.1016/C2009-0-24322-4, ISBN 978-0-7506-4552-2
  4. Gill, Adrian E. (1982). Atmosphere-ocean dynamics. International geophysics series. New York: Academic Press. pp. 231–237. ISBN 978-0-12-283522-3.
  5. ^ Talley, Lynne D.; Pickard, George L.; Emery, William J.; Swift, James H. (2011), "Introduction to Descriptive Physical Oceanography", Descriptive Physical Oceanography, Elsevier, pp. 211–221, doi:10.1016/b978-0-7506-4552-2.10001-0, ISBN 978-0-7506-4552-2
  6. Sverdrup, Harald (1947). "Wind-Driven Currents in a Baroclinic Ocean; with Application to the Equatorial Currents of the Eastern Pacific". Proceedings of the National Academy of Sciences. 33 (11): 318–326. Bibcode:1947PNAS...33..318S. doi:10.1073/pnas.33.11.318. ISSN 0027-8424. PMC 1079064. PMID 16588757.
  7. Gill, Adrian E. (1982). Atmosphere-ocean dynamics. International geophysics series. New York: Academic Press. pp. 326–328, 465–471. ISBN 978-0-12-283522-3.
  8. ^ Munk, Walter H. (1950-04-01). "On the Wind-Driven Ocean Circulation". Journal of the Atmospheric Sciences. 7 (2): 80–93. Bibcode:1950JAtS....7...80M. doi:10.1175/1520-0469(1950)007<0080:OTWDOC>2.0.CO;2. ISSN 1520-0469.
  9. ^ Pedlosky, Joseph (1987). Geophysical fluid dynamics (2nd ed.). New York: Springer. pp. 263–271. ISBN 978-0-387-96387-7.
  10. Stommel, Henry (1948). "The westward intensification of wind-driven ocean currents". Eos, Transactions American Geophysical Union. 29 (2): 202–206. Bibcode:1948TrAGU..29..202S. doi:10.1029/tr029i002p00202. ISSN 0002-8606.
  11. Pedlosky, Joseph (1987). Geophysical fluid dynamics (2nd ed.). New York: Springer. pp. 58–65. ISBN 978-0-387-96387-7.
  12. US Department of Commerce, National Oceanic and Atmospheric Administration. "What is the Sargasso Sea?". oceanservice.noaa.gov. Retrieved 2023-12-05.
  13. Imbol Koungue, Rodrigue Anicet; Brandt, Peter; Lübbecke, Joke; Prigent, Arthur; Martins, Meike Sena; Rodrigues, Regina R. (2021). "The 2019 Benguela Niño". Frontiers in Marine Science. 8. doi:10.3389/fmars.2021.800103. ISSN 2296-7745.
  14. Stramma, L.; Lutjeharms, J. R. E. (1997-03-15). "The flow field of the subtropical gyre of the South Indian Ocean". Journal of Geophysical Research: Oceans. 102 (C3): 5513–5530. Bibcode:1997JGR...102.5513S. doi:10.1029/96JC03455. ISSN 0148-0227.
  15. Beal, Lisa M.; De Ruijter, Wilhelmus P. M.; Biastoch, Arne; Zahn, Rainer (2011). "On the role of the Agulhas system in ocean circulation and climate". Nature. 472 (7344): 429–436. Bibcode:2011Natur.472..429B. doi:10.1038/nature09983. ISSN 1476-4687. PMID 21525925. S2CID 4424886.
  16. Karl, David M. (1999-05-01). "A Sea of Change: Biogeochemical Variability in the North Pacific Subtropical Gyre". Ecosystems. 2 (3): 181–214. Bibcode:1999Ecosy...2..181K. doi:10.1007/s100219900068. ISSN 1432-9840. S2CID 263452247.
  17. Toste, Raquel; de Freitas Assad, Luiz Paulo; Landau, Luiz (2019-11-01). "Changes in the North Pacific Current divergence and California Current transport based on HadGEM2-ES CMIP5 projections to the end of the century". Deep Sea Research Part II: Topical Studies in Oceanography. Understanding changes in transitional areas of the Pacific Ocean. 169–170: 104641. Bibcode:2019DSRII.16904641T. doi:10.1016/j.dsr2.2019.104641. ISSN 0967-0645. S2CID 202909021.
  18. Hristova, Hristina G.; Ladd, Carol; Stabeno, Phyllis J. (2019). "Variability and Trends of the Alaska Gyre From Argo and Satellite Altimetry". Journal of Geophysical Research: Oceans. 124 (8): 5870–5887. Bibcode:2019JGRC..124.5870H. doi:10.1029/2019JC015231. ISSN 2169-9275.
  19. ^ Day, Robert H.; Shaw, David G.; Ignell, Steven E. (1988). "The Quantitative Distribution and Characteristics of Neuston Plastic in the North Pacific Ocean, 1985–88. (Final Report to U.S. Department of Commerce, National Marine Fisheries Service, Auke Bay Laboratory. Auke Bay, Alaska)" (PDF). pp. 247–66. Archived (PDF) from the original on 19 August 2019. Retrieved 18 July 2008.
  20. Corp, Pelmorex (2020-07-27). "What lives in the Pacific's 'ocean desert'". The Weather Network. Retrieved 2023-12-05.
  21. US Department of Commerce, National Oceanic and Atmospheric Administration. "Where is Point Nemo?". oceanservice.noaa.gov. Retrieved 2023-12-05.
  22. Luo, Y.-W.; Doney, S. C.; Anderson, L. A.; Benavides, M.; Berman-Frank, I.; Bode, A.; Bonnet, S.; Boström, K. H.; Böttjer, D.; Capone, D. G.; Carpenter, E. J.; Chen, Y. L.; Church, M. J.; Dore, J. E.; Falcón, L. I. (2012-08-31). "Database of diazotrophs in global ocean: abundance, biomass and nitrogen fixation rates". Earth System Science Data. 4 (1): 47–73. Bibcode:2012ESSD....4...47L. doi:10.5194/essd-4-47-2012. hdl:10553/69784. ISSN 1866-3516.
  23. Bonnet, Sophie; Caffin, Mathieu; Berthelot, Hugo; Grosso, Olivier; Benavides, Mar; Helias-Nunige, Sandra; Guieu, Cécile; Stenegren, Marcus; Foster, Rachel Ann (2018-07-12). "In-depth characterization of diazotroph activity across the western tropical South Pacific hotspot of N2 fixation (OUTPACE cruise)". Biogeosciences. 15 (13): 4215–4232. doi:10.5194/bg-15-4215-2018. ISSN 1726-4170.
  24. EcoWatch (2013-01-17). "New Garbage Patch Discovered in the South Pacific Gyre". EcoWatch. Retrieved 2023-12-05.
  25. Wind Driven Surface Currents: Gyres oceanmotion.org/html accessed 5 December 2021
  26. ^ Koul, Vimal; Tesdal, Jan-Erik; Bersch, Manfred; Hátún, Hjálmar; Brune, Sebastian; Borchert, Leonard; Haak, Helmuth; Schrum, Corinna; Baehr, Johanna (2020-01-22). "Unraveling the choice of the north Atlantic subpolar gyre index". Scientific Reports. 10 (1): 1005. Bibcode:2020NatSR..10.1005K. doi:10.1038/s41598-020-57790-5. ISSN 2045-2322. PMC 6976698. PMID 31969636.
  27. Foukal, Nicholas P.; Lozier, M. Susan (2017). "Assessing variability in the size and strength of the North Atlantic subpolar gyre". Journal of Geophysical Research: Oceans. 122 (8): 6295–6308. Bibcode:2017JGRC..122.6295F. doi:10.1002/2017JC012798. ISSN 2169-9275.
  28. Orsi, Alejandro H.; Wiederwohl, Christina L. (2009). "A recount of Ross Sea waters". Deep Sea Research Part II: Topical Studies in Oceanography. 56 (13–14): 778–795. Bibcode:2009DSRII..56..778O. doi:10.1016/J.DSR2.2008.10.033.
  29. Rye, Craig D.; Marshall, John; Kelley, Maxwell; Russell, Gary; Nazarenko, Larissa S.; Kostov, Yavor; Schmidt, Gavin A.; Hansen, James (2020-06-16). "Antarctic Glacial Melt as a Driver of Recent Southern Ocean Climate Trends". Geophysical Research Letters. 47 (11). Bibcode:2020GeoRL..4786892R. doi:10.1029/2019GL086892. hdl:1721.1/133809.2. ISSN 0094-8276. S2CID 216320396.
  30. Rintoul, S. R.; Chown, S. L.; DeConto, R. M.; England, M. H.; Fricker, H. A.; Masson-Delmotte, V.; Naish, T. R.; Siegert, M. J.; Xavier, J. C. (2018). "Choosing the future of Antarctica". Nature. 558 (7709): 233–241. Bibcode:2018Natur.558..233R. doi:10.1038/s41586-018-0173-4. hdl:10044/1/60056. ISSN 1476-4687. PMID 29899481. S2CID 49193026.
  31. Dotto, Tiago S.; Naveira Garabato, Alberto; Bacon, Sheldon; Tsamados, Michel; Holland, Paul R.; Hooley, Jack; Frajka-Williams, Eleanor; Ridout, Andy; Meredith, Michael P. (2018-06-28). "Variability of the Ross Gyre, Southern Ocean: Drivers and Responses Revealed by Satellite Altimetry". Geophysical Research Letters. 45 (12): 6195–6204. Bibcode:2018GeoRL..45.6195D. doi:10.1029/2018GL078607. ISSN 0094-8276.
  32. ^ Yaremchuk, M.; Nechaev, D.; Schroter, J.; Fahrbach, E. (1998-08-31). "A dynamically consistent analysis of circulation and transports in the southwestern Weddell Sea". Annales Geophysicae. 16 (8): 1024–1038. Bibcode:1998AnGeo..16.1024Y. doi:10.1007/s00585-998-1024-7. ISSN 1432-0576.
  33. ^ Yaremchuk, M.; Nechaev, D.; Schroter, J.; Fahrbach, E. (1998-08-31). "A dynamically consistent analysis of circulation and transports in the southwestern Weddell Sea". Annales Geophysicae. 16 (8): 1024–1038. Bibcode:1998AnGeo..16.1024Y. doi:10.1007/s00585-998-1024-7. ISSN 0992-7689.
  34. Lin, Peigen; Pickart, Robert S.; Heorton, Harry; Tsamados, Michel; Itoh, Motoyo; Kikuchi, Takashi (2023). "Recent state transition of the Arctic Ocean's Beaufort Gyre". Nature Geoscience. 16 (6): 485–491. Bibcode:2023NatGe..16..485L. doi:10.1038/s41561-023-01184-5. ISSN 1752-0908. S2CID 258584160.
  35. Armitage, Thomas W. K.; Manucharyan, Georgy E.; Petty, Alek A.; Kwok, Ron; Thompson, Andrew F. (2020-02-06). "Enhanced eddy activity in the Beaufort Gyre in response to sea ice loss". Nature Communications. 11 (1): 761. Bibcode:2020NatCo..11..761A. doi:10.1038/s41467-020-14449-z. ISSN 2041-1723. PMC 7005044. PMID 32029737.
  36. Armitage, Thomas W. K.; Manucharyan, Georgy E.; Petty, Alek A.; Kwok, Ron; Thompson, Andrew F. (2020-02-06). "Enhanced eddy activity in the Beaufort Gyre in response to sea ice loss". Nature Communications. 11 (1): 761. Bibcode:2020NatCo..11..761A. doi:10.1038/s41467-020-14449-z. ISSN 2041-1723. PMC 7005044. PMID 32029737.
  37. ^ Cochran, J. Kirk; Bokuniewicz, Henry J.; Yager, Patricia L., eds. (2019). Encyclopedia of ocean sciences (3rd ed.). London, United Kingdom Cambridge, MA, United States: Academic Press is an imprint of Elsevier. pp. 753–756. ISBN 978-0-12-813081-0.
  38. Renfrow, Stephanie (2009-02-06). "An Ocean full of Deserts". Earthdata. Retrieved 2022-11-12.
  39. Gupta, Mukund; Williams, Richard G.; Lauderdale, Jonathan M.; Jahn, Oliver; Hill, Christopher; Dutkiewicz, Stephanie; Follows, Michael J. (2022-10-11). "A nutrient relay sustains subtropical ocean productivity". Proceedings of the National Academy of Sciences. 119 (41): e2206504119. Bibcode:2022PNAS..11906504G. doi:10.1073/pnas.2206504119. ISSN 0027-8424. PMC 9565266. PMID 36191202.
  40. Reintjes, Greta; Tegetmeyer, Halina E.; Bürgisser, Miriam; Orlić, Sandi; Tews, Ivo; Zubkov, Mikhail; Voß, Daniela; Zielinski, Oliver; Quast, Christian; Glöckner, Frank Oliver; Amann, Rudolf; Ferdelman, Timothy G.; Fuchs, Bernhard M. (2019-07-15). Nojiri, Hideaki (ed.). "On-Site Analysis of Bacterial Communities of the Ultraoligotrophic South Pacific Gyre". Applied and Environmental Microbiology. 85 (14). Bibcode:2019ApEnM..85E.184R. doi:10.1128/AEM.00184-19. ISSN 0099-2240. PMC 6606877. PMID 31076426.
  41. Regaudie-de-Gioux, A.; Huete-Ortega, M.; Sobrino, C.; López-Sandoval, D.C.; González, N.; Fernández-Carrera, A.; Vidal, M.; Marañón, E.; Cermeño, P.; Latasa, M.; Agustí, S.; Duarte, C.M. (2019). "Multi-model remote sensing assessment of primary production in the subtropical gyres". Journal of Marine Systems. 196: 97–106. Bibcode:2019JMS...196...97R. doi:10.1016/j.jmarsys.2019.03.007. hdl:10261/189755. S2CID 134102753.
  42. Signorini, Sergio R.; Franz, Bryan A.; McClain, Charles R. (2015). "Chlorophyll variability in the oligotrophic gyres: mechanisms, seasonality and trends". Frontiers in Marine Science. 2. doi:10.3389/fmars.2015.00001. ISSN 2296-7745.
  43. "Ocean Gyre". education.nationalgeographic.org. Retrieved 2023-11-28.
  44. Garcia, He; Weathers, Kw; Paver, Cr; Smolyar, I.; Boyer, Tp; Locarnini, Mm; Zweng, Mm; Mishonov, Av; Baranova, Ok; Seidov, D.; Reagan, Jr (2019-01-01). "World Ocean Atlas 2018. Vol. 4: Dissolved Inorganic Nutrients (phosphate, nitrate and nitrate+nitrite, silicate)". NOAA Atlas NESDIS 84.
  45. ^ Emerson, Steven; Hedges, John (2008-04-24). Chemical Oceanography and the Marine Carbon Cycle. Cambridge University Press. pp. 204–205. doi:10.1017/cbo9780511793202. ISBN 978-0-521-83313-4.
  46. Letscher, Robert T.; Primeau, François; Moore, J. Keith (October 2016). "Nutrient budgets in the subtropical ocean gyres dominated by lateral transport". Nature Geoscience. 9 (11): 815–819. Bibcode:2016NatGe...9..815L. doi:10.1038/ngeo2812. ISSN 1752-0908.
  47. Halm, Hannah; Lam, Phyllis; Ferdelman, Timothy G.; Lavik, Gaute; Dittmar, Thorsten; LaRoche, Julie; D'Hondt, Steven; Kuypers, Marcel MM (2012). "Heterotrophic organisms dominate nitrogen fixation in the South Pacific Gyre". The ISME Journal. 6 (6): 1238–1249. Bibcode:2012ISMEJ...6.1238H. doi:10.1038/ismej.2011.182. ISSN 1751-7370. PMC 3358028. PMID 22170429.
  48. Sohm, Jill A.; Webb, Eric A.; Capone, Douglas G. (2011). "Emerging patterns of marine nitrogen fixation". Nature Reviews Microbiology. 9 (7): 499–508. doi:10.1038/nrmicro2594. ISSN 1740-1534. PMID 21677685. S2CID 22129785.
  49. Nishioka, Jun; Obata, Hajime; Hirawake, Toru; Kondo, Yoshiko; Yamashita, Youhei; Misumi, Kazuhiro; Yasuda, Ichiro (2021-08-01). "A review: iron and nutrient supply in the subarctic Pacific and its impact on phytoplankton production". Journal of Oceanography. 77 (4): 561–587. Bibcode:2021JOce...77..561N. doi:10.1007/s10872-021-00606-5. ISSN 1573-868X.
  50. Martin, J. H.; Coale, K. H.; Johnson, K. S.; Fitzwater, S. E.; Gordon, R. M.; Tanner, S. J.; Hunter, C. N.; Elrod, V. A.; Nowicki, J. L.; Coley, T. L.; Barber, R. T.; Lindley, S.; Watson, A. J.; Van Scoy, K.; Law, C. S. (1994). "Testing the iron hypothesis in ecosystems of the equatorial Pacific Ocean". Nature. 371 (6493): 123–129. Bibcode:1994Natur.371..123M. doi:10.1038/371123a0. ISSN 1476-4687. S2CID 4369303.
  51. Coale, Kenneth H.; Johnson, Kenneth S.; Fitzwater, Steve E.; Gordon, R. Michael; Tanner, Sara; Chavez, Francisco P.; Ferioli, Laurie; Sakamoto, Carole; Rogers, Paul; Millero, Frank; Steinberg, Paul; Nightingale, Phil; Cooper, David; Cochlan, William P.; Landry, Michael R. (1996). "A massive phytoplankton bloom induced by an ecosystem-scale iron fertilization experiment in the equatorial Pacific Ocean". Nature. 383 (6600): 495–501. Bibcode:1996Natur.383..495C. doi:10.1038/383495a0. ISSN 1476-4687. PMID 18680864. S2CID 41323790.
  52. Martin, John H.; Gordon, R. Michael; Fitzwater, Steve; Broenkow, William W. (1989-05-01). "Vertex: phytoplankton/iron studies in the Gulf of Alaska". Deep Sea Research Part A. Oceanographic Research Papers. 36 (5): 649–680. Bibcode:1989DSRA...36..649M. doi:10.1016/0198-0149(89)90144-1. ISSN 0198-0149.
  53. Takahashi, Taro; Sutherland, Stewart C.; Sweeney, Colm; Poisson, Alain; Metzl, Nicolas; Tilbrook, Bronte; Bates, Nicolas; Wanninkhof, Rik; Feely, Richard A.; Sabine, Christopher; Olafsson, Jon; Nojiri, Yukihiro (2002-01-01). "Global sea–air CO2 flux based on climatological surface ocean pCO2, and seasonal biological and temperature effects". Deep Sea Research Part II: Topical Studies in Oceanography. The Southern Ocean I: Climatic Changes in the Cycle of Carbon in the Southern Ocean. 49 (9): 1601–1622. doi:10.1016/S0967-0645(02)00003-6. ISSN 0967-0645.
  54. ^ Richardson, Katherine; Bendtsen, Jørgen (2021). "Distinct Seasonal Primary Production Patterns in the Sub-Polar Gyre and Surrounding Seas". Frontiers in Marine Science. 8. doi:10.3389/fmars.2021.785685. ISSN 2296-7745.
  55. Cochran, J. Kirk; Bokuniewicz, Henry J.; Yager, Patricia L., eds. (2019). Encyclopedia of ocean sciences (3rd ed.). London, United Kingdom Cambridge, MA, United States: Academic Press is an imprint of Elsevier. p. 578. ISBN 978-0-12-813081-0.
  56. United Nations (March 2008). United Nations Declaration on the Rights of Indigenous Peoples. United Nations. p. 2.
  57. Gearheard, Shari; Aipellee, Gary; o'Keefe, Kyle (2010). "The Igliniit Project: Combining Inuit Knowledge and Geomatics Engineering to Develop a New Observation Tool for Hunters". SIKU: Knowing Our Ice. pp. 181–202. doi:10.1007/978-90-481-8587-0_8. ISBN 978-90-481-8586-3.
  58. Tripathy-Lang, Alka (2022-02-24). "Navigating the Pacific with Wind, Waves, and Stars". Eos. Retrieved 2023-12-06.
  59. "History". Hōkūleʻa. Retrieved 2023-12-06.
  60. Te Ahukaramū Charles Royal (June 12, 2006). "Tangaroa – the sea – The importance of the sea". Te Ara – the Encyclopedia of New Zealand.
  61. communications@waikato.ac.nz (2021-11-10). "Indigenous explorers' ancestral ocean stories relevant to climate crisis". www.waikato.ac.nz. Retrieved 2023-12-06.
  62. "Indigenous knowledge 'gives us a much richer picture': Q&A with Māori researcher Ocean Mercier". Mongabay Environmental News. 2022-02-25. Retrieved 2023-11-28.
  63. "Te Tai Uka a Pia | Deep South Challenge". Deep South Challenge | Climate Change Tools & Information. 2020-10-07. Retrieved 2023-11-28.
  64. Poleward shift of the major ocean gyres detected in a warming climate. Geophysical Research Letters, 47, e2019GL085868 doi:10.1029/2019GL085868
  65. Bard, E., & Rickaby, R. E. (2009). Migration of the subtropical front as a modulator of glacial climate. Nature, 460(7253), 380.
  66. Wind-driven evolution of the north pacific subpolar gyre over the last deglaciation. Geophys. Res. Lett. 47, 208–212 (2020).
  67. Climate Change is Pushing Giant Ocean Currents Poleward Bob Berwyn, 26 February 2020 insideclimatenews.org, accessed 5 December 2021
  68. Major Ocean Currents Drifting Poleward www.loe.org, accessed 5 December 2021
  69. ^ "Marine Debris in the North Pacific A Summary of Existing Information and Identification of Data Gaps" (PDF). United States Environmental Protection Agency. 24 July 2015.
  70. Maser, Chris (2014). Interactions of Land, Ocean and Humans: A Global Perspective. CRC Press. pp. 147–48. ISBN 978-1482226393.
  71. Jambeck, Jenna R.; Geyer, Roland; Wilcox, Chris (12 February 2015). "Plastic waste inputs from land into the ocean" (PDF). Science. 347 (6223): 769. Bibcode:2015Sci...347..768J. doi:10.1126/science.1260352. PMID 25678662. S2CID 206562155. Archived from the original (PDF) on 22 January 2019. Retrieved 28 August 2018.
  72. Christian Schmidt; Tobias Krauth; Stephan Wagner (11 October 2017). "Export of Plastic Debris by Rivers into the Sea" (PDF). Environmental Science & Technology. 51 (21): 12246–12253. Bibcode:2017EnST...5112246S. doi:10.1021/acs.est.7b02368. PMID 29019247. The 10 top-ranked rivers transport 88–95% of the global load into the sea
  73. Franzen, Harald (30 November 2017). "Almost all plastic in the ocean comes from just 10 rivers". Deutsche Welle. Retrieved 18 December 2018. It turns out that about 90 percent of all the plastic that reaches the world's oceans gets flushed through just 10 rivers: The Yangtze, the Indus, Yellow River, Hai River, the Nile, the Ganges, Pearl River, Amur River, the Niger, and the Mekong (in that order).
  74. Robert Lee Hotz (13 February 2015). "Asia Leads World in Dumping Plastic in Seas". Wall Street Journal. Archived from the original on 23 February 2015.
  75. Cózar, Andrés; Echevarría, Fidel; González-Gordillo, J. Ignacio; Irigoien, Xabier; Úbeda, Bárbara; Hernández-León, Santiago; Palma, Álvaro T.; Navarro, Sandra; García-de-Lomas, Juan; Ruiz, Andrea; Fernández-de-Puelles, María L. (2014-07-15). "Plastic debris in the open ocean". Proceedings of the National Academy of Sciences. 111 (28): 10239–10244. Bibcode:2014PNAS..11110239C. doi:10.1073/pnas.1314705111. ISSN 0027-8424. PMC 4104848. PMID 24982135.

External links

Ocean currents and gyres
Currents
Arctic Ocean
Atlantic Ocean
Indian Ocean
Pacific Ocean
Southern Ocean
Gyres
Major gyres
Other gyres
Related
icon Environment portal  icon Oceans portal
Physical oceanography
Waves Upwelling





Antarctic bottom water
Circulation
Tides
Landforms
Plate
tectonics
Ocean zones
Sea level
Acoustics
Satellites
Related
Categories: