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Norwegian Sea

March 15, 2023

This article is about the actual sea. For the cruise ship, see MS Norwegian Sea. For the ancient name of the Kattegat, see Kattegat.

The Norwegian Sea (Norwegian: Norskehavet; Icelandic: Noregshaf; Faroese: Norskahavið) is a marginal sea, grouped with either the Atlantic Ocean or the Arctic Ocean, northwest of Norway between the North Sea and the Greenland Sea, adjoining the Barents Sea to the northeast. In the southwest, it is separated from the Atlantic Ocean by a submarine ridge running between Iceland and the Faroe Islands. To the north, the Jan Mayen Ridge separates it from the Greenland Sea.

Norwegian Sea
The Vestfjorden with the mountains of the Lofoten archipelago seen from Løvøy Island in Steigen. Vågakaillen (942 m) is the taller of the two peaks in the centre of the image.
The Norwegian Sea is outlined in red (Europäisches Nordmeer in German)
LocationNorthern Europe
Coordinates69°N 2°E / 69°N 2°E / 69; 2Coordinates: 69°N 2°E / 69°N 2°E / 69; 2
TypeSea
Primary inflows
  • Central North Atlantic,
  • numerous Norwegian fjords
Basin countriesIceland, Norway, Denmark (Faroe Island) and United Kingdom (Shetland Island)
Surface area1,383,000 km2 (534,000 sq mi)
Average depth2,000 m (6,600 ft)
Max. depth3,970 m (13,020 ft)
Water volume2,000,000 km3 (1.6×1012 acre⋅ft)
References[1][2][3]

Unlike many other seas, most of the bottom of the Norwegian Sea is not part of a continental shelf and therefore lies at a great depth of about two kilometres on average. Rich deposits of oil and natural gas are found under the sea bottom and are being explored commercially, in the areas with sea depths of up to about one kilometre. The coastal zones are rich in fish that visit the Norwegian Sea from the North Atlantic or from the Barents Sea (cod) for spawning. The warm North Atlantic Current ensures relatively stable and high water temperatures, so that unlike the Arctic seas, the Norwegian Sea is ice-free throughout the year. Recent research has concluded that the large volume of water in the Norwegian Sea with its large heat absorption capacity is more important as a source of Norway's mild winters than the Gulf Stream and its extensions.[4]

Extent

The International Hydrographic Organization defines the limits of the Norwegian Sea as follows:[5]

On the Northeast. A line joining the southernmost point of West Spitzbergen [sic] to North Cape of Bear Island, through this island to Cape Bull and thence on to North Cape in Norway (25°45'E).
On the Southeast. The West coast of Norway between North Cape and Cape Stadt (62°10′N 5°00′E / 62.167°N 5.000°E / 62.167; 5.000 (Cape Stadt)).
On the South. From a point on the West coast of Norway in Latitude 61°00' North along this parallel to Longitude 0°53' West thence a line to the NE extreme of Fuglö (62°21′N 6°15′W / 62.350°N 6.250°W / 62.350; -6.250 (Fuglö)) and on to the East extreme of Gerpir (65°05′N 13°30′W / 65.083°N 13.500°W / 65.083; -13.500 (Gerpir)) in Iceland.
On the West. The Southeastern limit of Greenland Sea [A line joining the southernmost point of West Spitzbergen [sic] to the Northern point of Jan Mayen Island, down the West coast of that island to its Southern extreme, thence a Line to the Eastern extreme of Gerpir (65°05′N 13°30′W / 65.083°N 13.500°W / 65.083; -13.500 (Gerpir)) in Iceland].

Formation and geography

 
Norwegian Sea, surrounded by shallower seas to the south (North Sea) and northeast (Barents Sea). The white dot near the centre is Jan Mayen, and the dot between Spitsbergen (large island to the north) and Norway is Bear Island.
 
Vedøya, Skumvær and Røst islands, Lofoten, Norway

The Norwegian Sea was formed about 250 million years ago, when the Eurasian plate of Norway and the North American Plate, including Greenland, started to move apart. The existing narrow shelf sea between Norway and Greenland began to widen and deepen.[6] The present continental slope in the Norwegian Sea marks the border between Norway and Greenland as it stood approximately 250 million years ago. In the north it extends east from Svalbard and on the southwest between Britain and the Faroes. This continental slope contains rich fishing grounds and numerous coral reefs. Settling of the shelf after the separation of the continents has resulted in landslides, such as the Storegga Slide about 8,000 years ago that induced a major tsunami.[6]

The coasts of the Norwegian Sea were shaped during the last ice age. Large glaciers several kilometres high pushed into the land, forming fjords, removing the crust into the sea, and thereby extending the continental slopes. This is particularly clear off the Norwegian coast along Helgeland and north to the Lofoten Islands.[6] The Norwegian continental shelf is between 40 and 200 kilometres wide, and has a different shape from the shelves in the North Sea and Barents Sea. It contains numerous trenches and irregular peaks, which usually have an amplitude of less than 100 metres, but can reach up to 400 metres.[7] They are covered with a mixture of gravel, sand, and mud, and the trenches are used by fish as spawning grounds.[6] Deeper into the sea, there are two deep basins separated by a low ridge (its deepest point at 3,000 m) between the Vøring Plateau and Jan Mayen island. The southern basin is larger and deeper, with large areas between 3,500 and 4,000 metres deep. The northern basin is shallower at 3,200–3,300 metres, but contains many individual sites going down to 3,500 metres.[8] Submarine thresholds and continental slopes mark the borders of these basins with the adjacent seas. To the south lies the European continental shelf and the North Sea, to the east is the Eurasian continental shelf with the Barents Sea. To the west, the Scotland-Greenland Ridge separates the Norwegian Sea from the North Atlantic. This ridge is on average only 500 metres deep, only in a few places reaching the depth of 850 metres. To the north lie the Jan Mayen Ridge and Mohns Ridge, which lie at a depth of 2,000 metres, with some trenches reaching depths of about 2,600 metres.[8]

Hydrology

 
Tide ranges and tide times (hours after Bergen) along the Norwegian coast
 
Thermohaline circulation explains the formation of cold, dense deep water in the Norwegian Sea. The entire circulation pattern takes ~2000 years to complete.
 
Surface currents in the North Atlantic

Four major water masses originating in the Atlantic and Arctic oceans meet in the Norwegian Sea, and the associated currents are of fundamental importance for the global climate. The warm, salty North Atlantic Current flows in from the Atlantic Ocean, and the colder and less saline Norwegian Current originates in the North Sea. The so-called East Iceland Current transports cold water south from the Norwegian Sea toward Iceland and then east, along the Arctic Circle; this current occurs in the middle water layer. Deep water flows into the Norwegian Sea from the Greenland Sea.[8] The tides in the sea are semi-diurnal; that is, they rise twice a day, to a height of about 3.3 metres.[1]

Surface currents

The hydrology of the upper water layers is largely determined by the flow from the North Atlantic. It reaches a speed of 10 Sv (1 Sv = million m3/s) and its maximum depth is 700 metres at the Lofoten Islands, but normally it is within 500 metres.[8] Part of it comes through the Faroe-Shetland Channel and has a comparatively high salinity of 35.3‰ (parts per thousand). This current originates in the North Atlantic Current and passes along the European continental slope; increased evaporation due to the warm European climate results in the elevated salinity. Another part passes through the Greenland-Scotland trench between the Faroe Islands and Iceland; this water has a mean salinity between 35 and 35.2‰.[9] The flow shows strong seasonal variations and can be twice as high in winter as in summer.[7] While at the Faroe-Shetland Channel it has a temperature of about 9.5 °C; it cools to about 5 °C at Svalbard and releases this energy (about 250 terawatts) to the environment.[10][8]

The current flowing from the North Sea originates in the Baltic Sea and thus collects most of the drainage from northern Europe; this contribution is however relatively small.[7] The temperature and salinity of this current show strong seasonal and annual fluctuations. Long-term measurements within the top 50 metres near the coast show a maximum temperature of 11.2 °C at the 63° N parallel in September and a minimum of 3.9 °C at the North Cape in March. The salinity varies between 34.3 and 34.6‰ and is lowest in spring owing to the inflow of melted snow from rivers.[8] The largest rivers discharging into the sea are Namsen, Ranelva and Vefsna. They are all relatively short, but have a high discharge rate owing to their steep mountainous nature.[11]

A portion of the warm surface water flows directly, within the West Spitsbergen Current, from the Atlantic Ocean, off the Greenland Sea, to the Arctic Ocean. This current has a speed of 3–5 Sv and has a large impact on the climate.[12] Other surface water (~1 Sv) flows along the Norwegian coast in the direction of the Barents Sea. This water may cool enough in the Norwegian Sea to submerge into the deeper layers; there it displaces water that flows back into the North Atlantic.[13]

Arctic water from the East Iceland Current is mostly found in the southwestern part of the sea, near Greenland. Its properties also show significant annual fluctuations, with long-term average temperature being below 3 °C and salinity between 34.7 and 34.9‰.[8] The fraction of this water on the sea surface depends on the strength of the current, which in turn depends on the pressure difference between the Icelandic Low and Azores High: the larger the difference, the stronger the current.[14]

Deep-sea currents

The Norwegian Sea is connected with the Greenland Sea and the Arctic Ocean by the 2,600-metre deep Fram Strait.[15] The Norwegian Sea Deep Water (NSDW) occurs at depths exceeding 2,000 metres; this homogeneous layer with a salinity of 34.91‰ experiences little exchange with the adjacent seas. Its temperature is below 0 °C and drops to −1 °C at the ocean floor.[8] Compared with the deep waters of the surrounding seas, NSDW has more nutrients but less oxygen and is relatively old.[16]

The weak deep-water exchange with the Atlantic Ocean is due to the small depth of the relatively flat Greenland-Scotland Ridge between Scotland and Greenland, an offshoot of the Mid-Atlantic Ridge. Only four areas of the Greenland-Scotland Ridge are deeper than 500 metres: the Faroe-Bank Channel (about 850 metres), some parts of the Iceland-Faroe Ridge (about 600 metres), the Wyville-Thomson Ridge (620 metres), and areas between Greenland and the Denmark Strait (850 metres) – this is much shallower than the Norwegian Sea.[13][16] Cold deep water flows into the Atlantic through various channels: about 1.9 Sv through the Faroe Bank channel, 1.1 Sv through the Iceland-Faroe channel, and 0.1 Sv via the Wyville-Thomson Ridge.[17] The turbulence that occurs when the deep water falls behind the Greenland-Scotland Ridge into the deep Atlantic basin mixes the adjacent water layers and forms the North Atlantic Deep Water, one of two major deep-sea currents providing the deep ocean with oxygen.[18]

Climate

The thermohaline circulation affects the climate in the Norwegian Sea, and the regional climate can significantly deviate from average. There is also a difference of about 10 °C between the sea and the coastline. Temperatures rose between 1920 and 1960,[19] and the frequency of storms decreased in this period. The storminess was relatively high between 1880 and 1910, decreased significantly in 1910–1960, and then recovered to the original level.[11]

In contrast to the Greenland Sea and Arctic seas, the Norwegian Sea is ice-free year round, owing to its warm currents.[1] The convection between the relatively warm water and cold air in the winter plays an important role in the Arctic climate.[20] The 10-degree July isotherm (air temperature line) runs through the northern boundary of the Norwegian Sea and is often taken as the southern boundary of the Arctic.[21] In winter, the Norwegian Sea generally has the lowest air pressure in the entire Arctic and where most Icelandic Low depressions form. The water temperature in most parts of the sea is 2–7 °C in February and 8–12 °C in August.[1]

 
Phytoplankton bloom in the Norwegian Sea.

Flora and fauna

The Norwegian Sea is a transition zone between boreal and Arctic conditions, and thus contains flora and fauna characteristic of both climatic regions.[8] The southern limit of many Arctic species runs through the North Cape, Iceland, and the center of the Norwegian Sea, while the northern limit of boreal species lies near the borders of the Greenland Sea with the Norwegian Sea and Barents Sea; that is, these areas overlap. Some species like the scallop Chlamys islandica and capelin tend to occupy this area between the Atlantic and Arctic oceans.[22]

Plankton and sea bottom organisms

Most of the aquatic life in the Norwegian Sea is concentrated in the upper layers. Estimates for the entire North Atlantic are that only 2% of biomass is produced at depths below 1,000 metres and only 1.2% occurs near the sea floor.[23]

The blooming of the phytoplankton is dominated by chlorophyll and peaks around 20 May. The major phytoplankton forms are diatoms, in particular the genus Thalassiosira and Chaetoceros. After the spring bloom the haptophytes of the genus Phaecocystis pouchetti become dominant.[24]

Zooplankton is mostly represented by the copepods Calanus finmarchicus and Calanus hyperboreus, where the former occurs about four times more often than the latter and is mostly found in the Atlantic streams, whereas C. hyperboreus dominates the Arctic waters;[24] they are the main diet of most marine predators.[22] The most important krill species are Meganyctiphanes norvegica, Thyssanoessa inermis, and Thyssanoessa longicaudata.[24] In contrast to the Greenland Sea, there is a significant presence of calcareous plankton (Coccolithophore and Globigerinida) in the Norwegian Sea.[23] Plankton production strongly fluctuates between years. For example, C. finmarchicus yield was 28 g/m2 (dry weight) in 1995 and only 8 g/m2 in 1997; this correspondingly affected the population of all its predators.[24]

Shrimp of the species Pandalus borealis play an important role in the diet of fish, particularly cod and blue whiting, and mostly occur at depths between 200 and 300 metres. A special feature of the Norwegian Sea is extensive coral reefs of Lophelia pertusa, which provide shelter to various fish species. Although these corals are widespread in many peripheral areas of the North Atlantic, they never reach such amounts and concentrations as at the Norwegian continental slopes. However, they are at risk due to increasing trawling, which mechanically destroys the coral reefs.[24]

Fish

 
Atlantic herring

The Norwegian coastal waters are the most important spawning ground of the herring populations of the North Atlantic, and the hatching occurs in March. The eggs float to the surface and are washed off the coast by the northward current. Whereas a small herring population remains in the fjords and along the northern Norwegian coast, the majority spends the summer in the Barents Sea, where it feeds on the rich plankton. Upon reaching puberty, herring returns to the Norwegian Sea.[25] The herring stock varies greatly between years. It increased in the 1920s owing to the milder climate and then collapsed in the following decades until 1970; the decrease was, however, at least partly caused by overfishing.[19] The biomass of young hatched herring declined from 11 million tonnes in 1956 to almost zero in 1970;[22] that affected the ecosystem not only of the Norwegian Sea but also of the Barents Sea.[26]

 
Capelin is a common fish of the Atlantic-arctic transitional waters

Enforcement of environmental and fishing regulations has resulted in partial recovery of the herring populations since 1987.[19][22] This recovery was accompanied by a decline of capelin and cod stocks. While the capelin benefited from the reduced fishing, the temperature rise in the 1980s and competition for food with the herring resulted in a near disappearance of young capelin from the Norwegian Sea.[27] Meanwhile, the elderly capelin population was quickly fished out. This also reduced the population of cod – a major predator of capelin – as the herring was still too small in numbers to replace the capelin in the cod's diet.[27][28]

 
Blue whiting

Blue whiting (Micromesistius poutassou) has benefited from the decline of the herring and capelin stocks as it assumed the role of major predator of plankton. The blue whiting spawns near the British Isles. The sea currents carry their eggs to the Norwegian Sea, and the adults also swim there to benefit from the food supply. The young spend the summer and the winter until February in Norwegian coastal waters and then return to the warmer waters west of Scotland.[8] The Norwegian Arctic cod mostly occurs in the Barents Sea and at the Svalbard Archipelago. In the rest of the Norwegian Sea, it is found only during the reproduction season, at the Lofoten Islands,[25] whereas Pollachius virens and haddock spawn in the coastal waters.[8] Mackerel is an important commercial fish. The coral reefs are populated by different species of the genus Sebastes.[24]

Mammals and birds

 
Armhook squid Gonatus fabricii

Significant numbers of minke, humpback, sei, and orca whales are present in the Norwegian Sea,[29] and white-beaked dolphins occur in the coastal waters.[30] Orcas and some other whales visit the sea in the summer months for feeding; their population is closely related to the herring stocks, and they follow the herring schools within the sea.[24] With a total population of about 110,000, minke whales are by far the most common whales in the sea. They are hunted by Norway and Iceland, with a quota of about 1,000 per year in Norway. In contrast to the past, nowadays primarily their meat is consumed, rather than fat and oil.[31]

The bowhead whale used to be a major plankton predator, but it almost disappeared from the Norwegian Sea after intense whaling in the 19th century,[22] and was temporarily extinct in the entire North Atlantic. Similarly, the blue whale used to form large groups between Jan Mayen and Spitsbergen, but is hardly present nowadays.[32] Observations of northern bottlenose whales in the Norwegian Sea are rare.[33] Other large animals of the sea are hooded and harp seals and squid.[22]

Important waterfowl species of the Norwegian Sea are puffin, kittiwake and guillemot. Puffins and guillemots also suffered from the collapse of the herring population, especially the puffins on the Lofoten Islands. The latter hardly had an alternative to herring and their population was approximately halved between 1969 and 1987.[34]

Human activities

Norway, Iceland, and Denmark/Faroe Islands share the territorial waters of the Norwegian Sea, with the largest part belonging to the first. Norway has claimed twelve-mile limit as territorial waters since 2004 and an exclusive economic zone of 200 miles since 1976. Consequently, due to the Norwegian islands of Svalbard and Jan Mayen, the southeast, northeast and northwest edge of the sea fall within Norway. The southwest border is shared between Iceland and Denmark/Faroe Islands.[35]

According to the Føroyingasøga, Norse settlers arrived on the islands around the 8th Century. King Harald Fairhair is credited with being the driving force to colonize these islands as well as others in the Norwegian sea.[36]

The largest damage to the Norwegian Sea was caused by extensive fishing, whaling, and pollution. Other contamination is mostly by oil and toxic substances,[35] but also from the great number of ships sunk during the two world wars.[37] The environmental protection of the Norwegian Sea is mainly regulated by the OSPAR Convention.[35]

Fishing and whaling

 
Traditional cod stand
 
Arctic whaling (18th century). The ships are Dutch and the animals are bowhead whales. Beerenberg on Jan Mayen Land can be seen in the background.

Fishing has been practised near the Lofoten archipelago for hundreds of years. The coastal waters of the remote Lofoten islands are one of the richest fishing areas in Europe, as most of the Atlantic cod swims to the coastal waters of Lofoten in the winter to spawn. So in the 19th century, dried cod was one of Norway's main exports and by far the most important industry in northern Norway. Strong sea currents, maelstroms, and especially frequent storms made fishing a dangerous occupation: several hundred men died on the "Fatal Monday" in March 1821, 300 of them from a single parish, and about a hundred boats with their crews were lost within a short time in April 1875.[38]

Over the last century, the Norwegian Sea has been suffering from overfishing. In 2018, 41% of stocks were excessively harvested.[39] Two out of sixteen of the Total Allowed Catches (TACs) agreed upon by the European Union (EU) and Norway follow scientific advice. Nine of those TACs are at least 25% above scientific advice. While the other five are set above scientific evidence when excluding landing obligation.[40] Under the Common Fisheries Policy (CFP), the EU committed to phase out overfishing by 2015, 2020 at the absolute latest.[41] As of 2019, the EU was reported to not be on path to achieving that goal.[42]

Whaling was also important for the Norwegian Sea. In the early 1600s, the Englishman Stephen Bennet started hunting walrus at Bear Island. In May 1607 the Muscovy Company, while looking for the Northwest Passage and exploring the sea, discovered the large populations of walrus and whales in the Norwegian Sea and started hunting them in 1610 near Spitsbergen.[43] Later in the 17th century, Dutch ships started hunting bowhead whales near Jan Mayen; the bowhead population between Svalbard and Jan Mayen was then about 25,000 individuals.[44] Britons and Dutch were then joined by Germans, Danes, and Norwegians.[43] Between 1615 and 1820, the waters between Jan Mayen, Svalbard, Bear Island, and Greenland, between the Norwegian, Greenland, and Barents Seas, were the most productive whaling area in the world. However, extensive hunting had wiped out the whales in that region by the early 20th century.[32]

Sea monsters and maelstroms

 
The Carta Marina (1539) by Olaus Magnus is the earliest detailed map of the Nordic countries. Note various sea monsters on the map.
 
Illustration by Harry Clarke (1889–1931) for Edgar Allan Poe's story "Descent into the Maelstrom," published in 1919.

For many centuries, the Norwegian Sea was regarded as the edge of the known world. The disappearance of ships there, due to the natural disasters, induced legends of monsters that stopped and sank ships (kraken). As late as in 1845, the Encyclopædia metropolitana contained a multi-page review by Erik Pontoppidan (1698–1764) on ship-sinking sea monsters half a mile in size.[45] Many legends might be based on the work Historia de gentibus septentrionalibus of 1539 by Olaus Magnus, which described the kraken and maelstroms of the Norwegian Sea.[46] The kraken also appears in Alfred Tennyson's poem of the same name, in Herman Melville's Moby Dick, and in Twenty Thousand Leagues Under the Sea by Jules Verne.

Between the Lofoten islands of Moskenesøya and Værøy, at the tiny Mosken island, lies the Moskenstraumen – a system of tidal eddies and a whirlpool called a maelstrom. With a speed on the order of 15 km/h (9 mph) (the value strongly varies between sources), it is one of the strongest maelstroms in the world. It was described in the 13th century in the Old Norse Poetic Edda and remained an attractive subject for painters and writers, including Edgar Allan Poe, Walter Moers and Jules Verne. The word was introduced into the English language by Poe in his story "A Descent into the Maelström" (1841) describing the Moskenstraumen.[47] The Moskenstraumen is created as a result of a combination of several factors, including the tides, the position of the Lofoten, and the underwater topography; unlike most other whirlpools, it is located in the open sea rather than in a channel or bay. With a diameter of 40–50 metres, it can be dangerous even in modern times to small fishing vessels that might be attracted by the abundant cod feeding on the microorganisms sucked in by the whirlpool.[48]

Exploration

 
In the late 19th century, Henrik Mohn developed the first dynamic flow model of the North Atlantic. This map of 1904 shows surface and underwater currents.

The fish-rich coastal waters of northern Norway have long been known and attracted skilled sailors from Iceland and Greenland. Thus most settlements in Iceland and Greenland were on the west coasts of the islands, which were also warmer due to the Atlantic currents. The first reasonably reliable map of northern Europe, the Carta marina of 1539, represents the Norwegian Sea as coastal waters and shows nothing north of the North Cape. The Norwegian Sea off the coast regions appeared on the maps in the 17th century as an important part of the then sought Northern Sea Route and a rich whaling ground.[49]

Jan Mayen island was discovered in 1607 and become an important base of Dutch whalers. The Dutchman Willem Barents discovered Bear Island and Svalbard,[49] which was then used by Russian whalers called pomors. The islands on the edge of the Norwegian Sea have been rapidly divided between nations. During the peaks of whaling, some 300 ships with 12,000 crew members were yearly visiting Svalbard.[49]

The first depth measurements of the Norwegian Sea were performed in 1773 by Constantine Phipps aboard HMS Racehorse, as a part of his North Pole expedition.[50] Systematic oceanographic research in the Norwegian Sea started in the late 19th century, when declines in the yields of cod and herring off the Lofoten prompted the Norwegian government to investigate the matter.[51] The zoologist Georg Ossian Sars and meteorologist Henrik Mohn persuaded the government in 1874 to send out a scientific expedition, and between 1876 and 1878 they explored much of the sea aboard Vøringen.[52] The data obtained allowed Mohn to establish the first dynamic model of ocean currents, which incorporated winds, pressure differences, sea water temperature, and salinity and agreed well with later measurements.[53] In 2019, deposits of iron, copper, zink and cobalt were found on the Mohn Ridge, likely from hydrothermal vents.[54]

Navigation

 
HMS Sheffield during the winter convoy through the Norwegian Sea to Russia in 1941
 
Soviet nuclear submarine K-278 Komsomolets, 1986

Until the 20th century, the coasts of the Norwegian Sea were sparsely populated and therefore shipping in the sea was mostly focused on fishing, whaling, and occasional coastal transportation. Since the late 19th century, the Norwegian Coastal Express sea line has been established, connecting the more densely populated south with the north of Norway by at least one trip a day. The importance of shipping in the Norwegian Sea also increased with the expansion of the Russian and Soviet navies in the Barents Sea and development of international routes to the Atlantic through the Baltic Sea, Kattegat, Skagerrak, and North Sea.

The Norwegian Sea is ice-free and provides a direct route from the Atlantic to the Russian ports in the Arctic (Murmansk, Arkhangelsk, and Kandalaksha), which are directly linked to central Russia. This route was extensively used for supplies during World War II – of 811 US ships, 720 reached Russian ports, bringing some 4 million tonnes of cargo that included about 5,000 tanks and 7,000 aircraft. The Allies lost 18 convoys and 89 merchant ships on this route.[55] The major operations of the German Navy against the convoys included PQ 17 in July 1942, the Battle of the Barents Sea in December 1942, and the Battle of the North Cape in December 1943 and were carried out around the border between the Norwegian Sea and Barents Sea, near the North Cape.[55]

Navigation across the Norwegian Sea declined after World War II and intensified only in the 1960s–70s with the expansion of the Soviet Northern Fleet, which was reflected in major joint naval exercises of the Soviet Northern Baltic fleets in the Norwegian Sea. The sea was the gateway for the Soviet Navy to the Atlantic Ocean and thus to the United States, and the major Soviet port of Murmansk was just behind the border of the Norwegian and Barents Sea.[56] The countermeasures by the NATO countries resulted in a significant naval presence in the Norwegian Sea and intense cat-and-mouse games between Soviet and NATO aircraft, ships, and especially submarines.[57] A relic of the Cold War in the Norwegian Sea, the Soviet nuclear submarine K-278 Komsomolets, sank in 1989 southwest of Bear Island, at the border of the Norwegian and Barents seas, with radioactive material onboard that poses potential danger to flora and fauna.[58]

The Norwegian Sea is part of the Northern Sea Route for ships from European ports to Asia. The travel distance from Rotterdam to Tokyo is 21,100 km (13,111 mi) via the Suez Canal and only 14,100 km (8,761 mi) through the Norwegian Sea. Sea ice is a common problem in the Arctic seas, but ice-free conditions along the entire northern route were observed at the end of August 2008.[59] Russia is planning to expand its offshore oil production in the Arctic, which should increase the traffic of tankers through the Norwegian Sea to markets in Europe and America; it is expected that the number of oil shipments through the northern Norwegian Sea will increase from 166 in 2002 to 615 in 2015.[60]

 
Map of the Langeled pipeline

Oil and gas

The most important products of the Norwegian Sea are no longer fish, but oil and especially gas found under the ocean floor.[61] Norway started undersea oil production in 1993, followed by development of the Huldra gas field in 2001.[62] The large depth and harsh waters of the Norwegian Sea pose significant technical challenges for offshore drilling.[63] Whereas drilling at depths exceeding 500 metres has been conducted since 1995, only a few deep gas fields have been explored commercially. The most important current project is Ormen Lange (depth 800–1,100 m), where gas production started in 2007. With reserves of 4.0×1011 m3 (1.4×1013 cu ft), it is the major Norwegian gas field. It is connected to the Langeled pipeline, currently the world's longest underwater pipeline, and thus to a major European gas pipeline network.[64][65] Several other gas fields are being developed. As of 2019, there is an estimated 6.5 hm3 of crude oil in the Norwegian Sea, with an expectation to increase oil production in the region up until 2025. A particular challenge is the Kristin field, where the temperature is as high as 170 °C and the gas pressure exceeds 900 bar (900 times the normal pressure).[63] Further north are Norne and Snøhvit.

In popular culture

In the popular fishing game Russian Fishing 4, Norwegian Sea is the newest map for fishing, especially boat fishing.[66]

See also

References

  1. ^ a b c d Norwegian Sea, Great Soviet Encyclopedia (in Russian)
  2. ^ Norwegian Sea, Encyclopædia Britannica on-line
  3. ^ ICES, 2007, p. 1
  4. ^ Westerly storms warm Norway 2018-09-29 at the Wayback Machine. The Research Council of Norway. Forskningsradet.no (3 September 2012). Retrieved on 2013-03-21.
  5. ^ (PDF). International Hydrographic Organization. 1953. Archived from the original (PDF) on 8 October 2011. Retrieved 28 December 2020.
  6. ^ a b c d Terje Thornes & Oddvar Longva "The origin of the coastal zone" in: Sætre, 2007, pp. 35–43
  7. ^ a b c Sætre, 2007, pp. 44–58
  8. ^ a b c d e f g h i j k Blindheim, 1989, pp. 366–382
  9. ^ Aken, 2007, pp. 119–124
  10. ^ Roald Sætre Driving forces in: Sætre, 2007, pp. 44–58
  11. ^ a b Matti Seppälä The Physical Geography of Fennoscandia, Oxford University Press, 2005 ISBN 0-19-924590-8, pp. 121–141
  12. ^ Tyler, 2003, pp. 45–49
  13. ^ a b Tyler, 2003, pp. 115–116
  14. ^ ICES, 2007, pp. 2–4
  15. ^ Tyler, 2003, pp. 240–260
  16. ^ a b Aken, 2007, pp. 131–138
  17. ^ Skreslet & NATO, 2005, p. 93
  18. ^ Ronald E. Hester, Roy M. Harrison Biodiversity Under Threat, Royal Society of Chemistry, 2007 ISBN 0-85404-251-2, p. 96
  19. ^ a b c Gerold Wefer, Frank Lamy, Fauzi Mantoura Marine Science Frontiers for Europe, Springer, 2003 ISBN 3-540-40168-7, pp. 32–35
  20. ^ Schaefer, 2001, pp. 10–17
  21. ^ Kieran Mulvaney At the Ends of the Earth: A History of the Polar Regions, Iceland Press, 2001 ISBN 1-55963-908-3, p. 23
  22. ^ a b c d e f Skreslet & NATO, 2005, pp. 103–114
  23. ^ a b Andrea Schröder-Ritzrau et al., Distribution, export and alteration of plankton in the Norwegian Sea Fossiliziable. Schaefer, 2001, pp. 81–104
  24. ^ a b c d e f g ICES, 2007, pp. 5–8
  25. ^ a b Blindheim, 1989, pp. 382–401
  26. ^ Olav Schram Stokke Governing High Seas Fisheries: The Interplay of Global and Regional regime, Oxford University Press, 2001 ISBN 0-19-829949-4, pp. 241–255
  27. ^ a b Gene S. Helfman Fish Conservation: A Guide to Understanding and Restoring Global Aquatic Biodiversity and Fishery Resources, Iceland Press, 2007 ISBN 1-55963-595-9, pp. 321–323
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Bibliography

External links

March 15, 2023
norwegian, this, article, about, actual, cruise, ship, ancient, name, kattegat, kattegat, norwegian, norskehavet, icelandic, noregshaf, faroese, norskahavið, marginal, grouped, with, either, atlantic, ocean, arctic, ocean, northwest, norway, between, north, gr. This article is about the actual sea For the cruise ship see MS Norwegian Sea For the ancient name of the Kattegat see Kattegat The Norwegian Sea Norwegian Norskehavet Icelandic Noregshaf Faroese Norskahavid is a marginal sea grouped with either the Atlantic Ocean or the Arctic Ocean northwest of Norway between the North Sea and the Greenland Sea adjoining the Barents Sea to the northeast In the southwest it is separated from the Atlantic Ocean by a submarine ridge running between Iceland and the Faroe Islands To the north the Jan Mayen Ridge separates it from the Greenland Sea Norwegian SeaThe Vestfjorden with the mountains of the Lofoten archipelago seen from Lovoy Island in Steigen Vagakaillen 942 m is the taller of the two peaks in the centre of the image The Norwegian Sea is outlined in red Europaisches Nordmeer in German LocationNorthern EuropeCoordinates69 N 2 E 69 N 2 E 69 2 Coordinates 69 N 2 E 69 N 2 E 69 2TypeSeaPrimary inflowsCentral North Atlantic numerous Norwegian fjordsBasin countriesIceland Norway Denmark Faroe Island and United Kingdom Shetland Island Surface area1 383 000 km2 534 000 sq mi Average depth2 000 m 6 600 ft Max depth3 970 m 13 020 ft Water volume2 000 000 km3 1 6 1012 acre ft References 1 2 3 Unlike many other seas most of the bottom of the Norwegian Sea is not part of a continental shelf and therefore lies at a great depth of about two kilometres on average Rich deposits of oil and natural gas are found under the sea bottom and are being explored commercially in the areas with sea depths of up to about one kilometre The coastal zones are rich in fish that visit the Norwegian Sea from the North Atlantic or from the Barents Sea cod for spawning The warm North Atlantic Current ensures relatively stable and high water temperatures so that unlike the Arctic seas the Norwegian Sea is ice free throughout the year Recent research has concluded that the large volume of water in the Norwegian Sea with its large heat absorption capacity is more important as a source of Norway s mild winters than the Gulf Stream and its extensions 4 Contents 1 Extent 2 Formation and geography 3 Hydrology 3 1 Surface currents 3 2 Deep sea currents 4 Climate 5 Flora and fauna 5 1 Plankton and sea bottom organisms 5 2 Fish 5 3 Mammals and birds 6 Human activities 6 1 Fishing and whaling 6 2 Sea monsters and maelstroms 6 3 Exploration 6 4 Navigation 6 5 Oil and gas 7 In popular culture 8 See also 9 References 10 Bibliography 11 External linksExtent EditThe International Hydrographic Organization defines the limits of the Norwegian Sea as follows 5 On the Northeast A line joining the southernmost point of West Spitzbergen sic to North Cape of Bear Island through this island to Cape Bull and thence on to North Cape in Norway 25 45 E dd On the Southeast The West coast of Norway between North Cape and Cape Stadt 62 10 N 5 00 E 62 167 N 5 000 E 62 167 5 000 Cape Stadt dd On the South From a point on the West coast of Norway in Latitude 61 00 North along this parallel to Longitude 0 53 West thence a line to the NE extreme of Fuglo 62 21 N 6 15 W 62 350 N 6 250 W 62 350 6 250 Fuglo and on to the East extreme of Gerpir 65 05 N 13 30 W 65 083 N 13 500 W 65 083 13 500 Gerpir in Iceland dd On the West The Southeastern limit of Greenland Sea A line joining the southernmost point of West Spitzbergen sic to the Northern point of Jan Mayen Island down the West coast of that island to its Southern extreme thence a Line to the Eastern extreme of Gerpir 65 05 N 13 30 W 65 083 N 13 500 W 65 083 13 500 Gerpir in Iceland dd Formation and geography Edit Norwegian Sea surrounded by shallower seas to the south North Sea and northeast Barents Sea The white dot near the centre is Jan Mayen and the dot between Spitsbergen large island to the north and Norway is Bear Island Vedoya Skumvaer and Rost islands Lofoten Norway The Norwegian Sea was formed about 250 million years ago when the Eurasian plate of Norway and the North American Plate including Greenland started to move apart The existing narrow shelf sea between Norway and Greenland began to widen and deepen 6 The present continental slope in the Norwegian Sea marks the border between Norway and Greenland as it stood approximately 250 million years ago In the north it extends east from Svalbard and on the southwest between Britain and the Faroes This continental slope contains rich fishing grounds and numerous coral reefs Settling of the shelf after the separation of the continents has resulted in landslides such as the Storegga Slide about 8 000 years ago that induced a major tsunami 6 The coasts of the Norwegian Sea were shaped during the last ice age Large glaciers several kilometres high pushed into the land forming fjords removing the crust into the sea and thereby extending the continental slopes This is particularly clear off the Norwegian coast along Helgeland and north to the Lofoten Islands 6 The Norwegian continental shelf is between 40 and 200 kilometres wide and has a different shape from the shelves in the North Sea and Barents Sea It contains numerous trenches and irregular peaks which usually have an amplitude of less than 100 metres but can reach up to 400 metres 7 They are covered with a mixture of gravel sand and mud and the trenches are used by fish as spawning grounds 6 Deeper into the sea there are two deep basins separated by a low ridge its deepest point at 3 000 m between the Voring Plateau and Jan Mayen island The southern basin is larger and deeper with large areas between 3 500 and 4 000 metres deep The northern basin is shallower at 3 200 3 300 metres but contains many individual sites going down to 3 500 metres 8 Submarine thresholds and continental slopes mark the borders of these basins with the adjacent seas To the south lies the European continental shelf and the North Sea to the east is the Eurasian continental shelf with the Barents Sea To the west the Scotland Greenland Ridge separates the Norwegian Sea from the North Atlantic This ridge is on average only 500 metres deep only in a few places reaching the depth of 850 metres To the north lie the Jan Mayen Ridge and Mohns Ridge which lie at a depth of 2 000 metres with some trenches reaching depths of about 2 600 metres 8 Hydrology Edit Tide ranges and tide times hours after Bergen along the Norwegian coast Thermohaline circulation explains the formation of cold dense deep water in the Norwegian Sea The entire circulation pattern takes 2000 years to complete Surface currents in the North Atlantic Four major water masses originating in the Atlantic and Arctic oceans meet in the Norwegian Sea and the associated currents are of fundamental importance for the global climate The warm salty North Atlantic Current flows in from the Atlantic Ocean and the colder and less saline Norwegian Current originates in the North Sea The so called East Iceland Current transports cold water south from the Norwegian Sea toward Iceland and then east along the Arctic Circle this current occurs in the middle water layer Deep water flows into the Norwegian Sea from the Greenland Sea 8 The tides in the sea are semi diurnal that is they rise twice a day to a height of about 3 3 metres 1 Surface currents Edit The hydrology of the upper water layers is largely determined by the flow from the North Atlantic It reaches a speed of 10 Sv 1 Sv million m3 s and its maximum depth is 700 metres at the Lofoten Islands but normally it is within 500 metres 8 Part of it comes through the Faroe Shetland Channel and has a comparatively high salinity of 35 3 parts per thousand This current originates in the North Atlantic Current and passes along the European continental slope increased evaporation due to the warm European climate results in the elevated salinity Another part passes through the Greenland Scotland trench between the Faroe Islands and Iceland this water has a mean salinity between 35 and 35 2 9 The flow shows strong seasonal variations and can be twice as high in winter as in summer 7 While at the Faroe Shetland Channel it has a temperature of about 9 5 C it cools to about 5 C at Svalbard and releases this energy about 250 terawatts to the environment 10 8 The current flowing from the North Sea originates in the Baltic Sea and thus collects most of the drainage from northern Europe this contribution is however relatively small 7 The temperature and salinity of this current show strong seasonal and annual fluctuations Long term measurements within the top 50 metres near the coast show a maximum temperature of 11 2 C at the 63 N parallel in September and a minimum of 3 9 C at the North Cape in March The salinity varies between 34 3 and 34 6 and is lowest in spring owing to the inflow of melted snow from rivers 8 The largest rivers discharging into the sea are Namsen Ranelva and Vefsna They are all relatively short but have a high discharge rate owing to their steep mountainous nature 11 A portion of the warm surface water flows directly within the West Spitsbergen Current from the Atlantic Ocean off the Greenland Sea to the Arctic Ocean This current has a speed of 3 5 Sv and has a large impact on the climate 12 Other surface water 1 Sv flows along the Norwegian coast in the direction of the Barents Sea This water may cool enough in the Norwegian Sea to submerge into the deeper layers there it displaces water that flows back into the North Atlantic 13 Arctic water from the East Iceland Current is mostly found in the southwestern part of the sea near Greenland Its properties also show significant annual fluctuations with long term average temperature being below 3 C and salinity between 34 7 and 34 9 8 The fraction of this water on the sea surface depends on the strength of the current which in turn depends on the pressure difference between the Icelandic Low and Azores High the larger the difference the stronger the current 14 Deep sea currents Edit The Norwegian Sea is connected with the Greenland Sea and the Arctic Ocean by the 2 600 metre deep Fram Strait 15 The Norwegian Sea Deep Water NSDW occurs at depths exceeding 2 000 metres this homogeneous layer with a salinity of 34 91 experiences little exchange with the adjacent seas Its temperature is below 0 C and drops to 1 C at the ocean floor 8 Compared with the deep waters of the surrounding seas NSDW has more nutrients but less oxygen and is relatively old 16 The weak deep water exchange with the Atlantic Ocean is due to the small depth of the relatively flat Greenland Scotland Ridge between Scotland and Greenland an offshoot of the Mid Atlantic Ridge Only four areas of the Greenland Scotland Ridge are deeper than 500 metres the Faroe Bank Channel about 850 metres some parts of the Iceland Faroe Ridge about 600 metres the Wyville Thomson Ridge 620 metres and areas between Greenland and the Denmark Strait 850 metres this is much shallower than the Norwegian Sea 13 16 Cold deep water flows into the Atlantic through various channels about 1 9 Sv through the Faroe Bank channel 1 1 Sv through the Iceland Faroe channel and 0 1 Sv via the Wyville Thomson Ridge 17 The turbulence that occurs when the deep water falls behind the Greenland Scotland Ridge into the deep Atlantic basin mixes the adjacent water layers and forms the North Atlantic Deep Water one of two major deep sea currents providing the deep ocean with oxygen 18 Climate EditThe thermohaline circulation affects the climate in the Norwegian Sea and the regional climate can significantly deviate from average There is also a difference of about 10 C between the sea and the coastline Temperatures rose between 1920 and 1960 19 and the frequency of storms decreased in this period The storminess was relatively high between 1880 and 1910 decreased significantly in 1910 1960 and then recovered to the original level 11 In contrast to the Greenland Sea and Arctic seas the Norwegian Sea is ice free year round owing to its warm currents 1 The convection between the relatively warm water and cold air in the winter plays an important role in the Arctic climate 20 The 10 degree July isotherm air temperature line runs through the northern boundary of the Norwegian Sea and is often taken as the southern boundary of the Arctic 21 In winter the Norwegian Sea generally has the lowest air pressure in the entire Arctic and where most Icelandic Low depressions form The water temperature in most parts of the sea is 2 7 C in February and 8 12 C in August 1 Phytoplankton bloom in the Norwegian Sea Flora and fauna EditThe Norwegian Sea is a transition zone between boreal and Arctic conditions and thus contains flora and fauna characteristic of both climatic regions 8 The southern limit of many Arctic species runs through the North Cape Iceland and the center of the Norwegian Sea while the northern limit of boreal species lies near the borders of the Greenland Sea with the Norwegian Sea and Barents Sea that is these areas overlap Some species like the scallop Chlamys islandica and capelin tend to occupy this area between the Atlantic and Arctic oceans 22 Plankton and sea bottom organisms Edit Most of the aquatic life in the Norwegian Sea is concentrated in the upper layers Estimates for the entire North Atlantic are that only 2 of biomass is produced at depths below 1 000 metres and only 1 2 occurs near the sea floor 23 The blooming of the phytoplankton is dominated by chlorophyll and peaks around 20 May The major phytoplankton forms are diatoms in particular the genus Thalassiosira and Chaetoceros After the spring bloom the haptophytes of the genus Phaecocystis pouchetti become dominant 24 Hyperiidea Shrimp Pandalus borealis Lophelia pertusa Meganyctiphanes norvegicaZooplankton is mostly represented by the copepods Calanus finmarchicus and Calanus hyperboreus where the former occurs about four times more often than the latter and is mostly found in the Atlantic streams whereas C hyperboreus dominates the Arctic waters 24 they are the main diet of most marine predators 22 The most important krill species are Meganyctiphanes norvegica Thyssanoessa inermis and Thyssanoessa longicaudata 24 In contrast to the Greenland Sea there is a significant presence of calcareous plankton Coccolithophore and Globigerinida in the Norwegian Sea 23 Plankton production strongly fluctuates between years For example C finmarchicus yield was 28 g m2 dry weight in 1995 and only 8 g m2 in 1997 this correspondingly affected the population of all its predators 24 Shrimp of the species Pandalus borealis play an important role in the diet of fish particularly cod and blue whiting and mostly occur at depths between 200 and 300 metres A special feature of the Norwegian Sea is extensive coral reefs of Lophelia pertusa which provide shelter to various fish species Although these corals are widespread in many peripheral areas of the North Atlantic they never reach such amounts and concentrations as at the Norwegian continental slopes However they are at risk due to increasing trawling which mechanically destroys the coral reefs 24 Fish Edit Atlantic herring The Norwegian coastal waters are the most important spawning ground of the herring populations of the North Atlantic and the hatching occurs in March The eggs float to the surface and are washed off the coast by the northward current Whereas a small herring population remains in the fjords and along the northern Norwegian coast the majority spends the summer in the Barents Sea where it feeds on the rich plankton Upon reaching puberty herring returns to the Norwegian Sea 25 The herring stock varies greatly between years It increased in the 1920s owing to the milder climate and then collapsed in the following decades until 1970 the decrease was however at least partly caused by overfishing 19 The biomass of young hatched herring declined from 11 million tonnes in 1956 to almost zero in 1970 22 that affected the ecosystem not only of the Norwegian Sea but also of the Barents Sea 26 Capelin is a common fish of the Atlantic arctic transitional waters Enforcement of environmental and fishing regulations has resulted in partial recovery of the herring populations since 1987 19 22 This recovery was accompanied by a decline of capelin and cod stocks While the capelin benefited from the reduced fishing the temperature rise in the 1980s and competition for food with the herring resulted in a near disappearance of young capelin from the Norwegian Sea 27 Meanwhile the elderly capelin population was quickly fished out This also reduced the population of cod a major predator of capelin as the herring was still too small in numbers to replace the capelin in the cod s diet 27 28 Blue whiting Blue whiting Micromesistius poutassou has benefited from the decline of the herring and capelin stocks as it assumed the role of major predator of plankton The blue whiting spawns near the British Isles The sea currents carry their eggs to the Norwegian Sea and the adults also swim there to benefit from the food supply The young spend the summer and the winter until February in Norwegian coastal waters and then return to the warmer waters west of Scotland 8 The Norwegian Arctic cod mostly occurs in the Barents Sea and at the Svalbard Archipelago In the rest of the Norwegian Sea it is found only during the reproduction season at the Lofoten Islands 25 whereas Pollachius virens and haddock spawn in the coastal waters 8 Mackerel is an important commercial fish The coral reefs are populated by different species of the genus Sebastes 24 Mammals and birds Edit Armhook squid Gonatus fabricii Significant numbers of minke humpback sei and orca whales are present in the Norwegian Sea 29 and white beaked dolphins occur in the coastal waters 30 Orcas and some other whales visit the sea in the summer months for feeding their population is closely related to the herring stocks and they follow the herring schools within the sea 24 With a total population of about 110 000 minke whales are by far the most common whales in the sea They are hunted by Norway and Iceland with a quota of about 1 000 per year in Norway In contrast to the past nowadays primarily their meat is consumed rather than fat and oil 31 The bowhead whale used to be a major plankton predator but it almost disappeared from the Norwegian Sea after intense whaling in the 19th century 22 and was temporarily extinct in the entire North Atlantic Similarly the blue whale used to form large groups between Jan Mayen and Spitsbergen but is hardly present nowadays 32 Observations of northern bottlenose whales in the Norwegian Sea are rare 33 Other large animals of the sea are hooded and harp seals and squid 22 Important waterfowl species of the Norwegian Sea are puffin kittiwake and guillemot Puffins and guillemots also suffered from the collapse of the herring population especially the puffins on the Lofoten Islands The latter hardly had an alternative to herring and their population was approximately halved between 1969 and 1987 34 Human activities EditNorway Iceland and Denmark Faroe Islands share the territorial waters of the Norwegian Sea with the largest part belonging to the first Norway has claimed twelve mile limit as territorial waters since 2004 and an exclusive economic zone of 200 miles since 1976 Consequently due to the Norwegian islands of Svalbard and Jan Mayen the southeast northeast and northwest edge of the sea fall within Norway The southwest border is shared between Iceland and Denmark Faroe Islands 35 According to the Foroyingasoga Norse settlers arrived on the islands around the 8th Century King Harald Fairhair is credited with being the driving force to colonize these islands as well as others in the Norwegian sea 36 The largest damage to the Norwegian Sea was caused by extensive fishing whaling and pollution Other contamination is mostly by oil and toxic substances 35 but also from the great number of ships sunk during the two world wars 37 The environmental protection of the Norwegian Sea is mainly regulated by the OSPAR Convention 35 Fishing and whaling Edit Traditional cod stand Arctic whaling 18th century The ships are Dutch and the animals are bowhead whales Beerenberg on Jan Mayen Land can be seen in the background Fishing has been practised near the Lofoten archipelago for hundreds of years The coastal waters of the remote Lofoten islands are one of the richest fishing areas in Europe as most of the Atlantic cod swims to the coastal waters of Lofoten in the winter to spawn So in the 19th century dried cod was one of Norway s main exports and by far the most important industry in northern Norway Strong sea currents maelstroms and especially frequent storms made fishing a dangerous occupation several hundred men died on the Fatal Monday in March 1821 300 of them from a single parish and about a hundred boats with their crews were lost within a short time in April 1875 38 Over the last century the Norwegian Sea has been suffering from overfishing In 2018 41 of stocks were excessively harvested 39 Two out of sixteen of the Total Allowed Catches TACs agreed upon by the European Union EU and Norway follow scientific advice Nine of those TACs are at least 25 above scientific advice While the other five are set above scientific evidence when excluding landing obligation 40 Under the Common Fisheries Policy CFP the EU committed to phase out overfishing by 2015 2020 at the absolute latest 41 As of 2019 the EU was reported to not be on path to achieving that goal 42 Whaling was also important for the Norwegian Sea In the early 1600s the Englishman Stephen Bennet started hunting walrus at Bear Island In May 1607 the Muscovy Company while looking for the Northwest Passage and exploring the sea discovered the large populations of walrus and whales in the Norwegian Sea and started hunting them in 1610 near Spitsbergen 43 Later in the 17th century Dutch ships started hunting bowhead whales near Jan Mayen the bowhead population between Svalbard and Jan Mayen was then about 25 000 individuals 44 Britons and Dutch were then joined by Germans Danes and Norwegians 43 Between 1615 and 1820 the waters between Jan Mayen Svalbard Bear Island and Greenland between the Norwegian Greenland and Barents Seas were the most productive whaling area in the world However extensive hunting had wiped out the whales in that region by the early 20th century 32 Sea monsters and maelstroms Edit The Carta Marina 1539 by Olaus Magnus is the earliest detailed map of the Nordic countries Note various sea monsters on the map Illustration by Harry Clarke 1889 1931 for Edgar Allan Poe s story Descent into the Maelstrom published in 1919 For many centuries the Norwegian Sea was regarded as the edge of the known world The disappearance of ships there due to the natural disasters induced legends of monsters that stopped and sank ships kraken As late as in 1845 the Encyclopaedia metropolitana contained a multi page review by Erik Pontoppidan 1698 1764 on ship sinking sea monsters half a mile in size 45 Many legends might be based on the work Historia de gentibus septentrionalibus of 1539 by Olaus Magnus which described the kraken and maelstroms of the Norwegian Sea 46 The kraken also appears in Alfred Tennyson s poem of the same name in Herman Melville s Moby Dick and in Twenty Thousand Leagues Under the Sea by Jules Verne Between the Lofoten islands of Moskenesoya and Vaeroy at the tiny Mosken island lies the Moskenstraumen a system of tidal eddies and a whirlpool called a maelstrom With a speed on the order of 15 km h 9 mph the value strongly varies between sources it is one of the strongest maelstroms in the world It was described in the 13th century in the Old Norse Poetic Edda and remained an attractive subject for painters and writers including Edgar Allan Poe Walter Moers and Jules Verne The word was introduced into the English language by Poe in his story A Descent into the Maelstrom 1841 describing the Moskenstraumen 47 The Moskenstraumen is created as a result of a combination of several factors including the tides the position of the Lofoten and the underwater topography unlike most other whirlpools it is located in the open sea rather than in a channel or bay With a diameter of 40 50 metres it can be dangerous even in modern times to small fishing vessels that might be attracted by the abundant cod feeding on the microorganisms sucked in by the whirlpool 48 Exploration Edit In the late 19th century Henrik Mohn developed the first dynamic flow model of the North Atlantic This map of 1904 shows surface and underwater currents The fish rich coastal waters of northern Norway have long been known and attracted skilled sailors from Iceland and Greenland Thus most settlements in Iceland and Greenland were on the west coasts of the islands which were also warmer due to the Atlantic currents The first reasonably reliable map of northern Europe the Carta marina of 1539 represents the Norwegian Sea as coastal waters and shows nothing north of the North Cape The Norwegian Sea off the coast regions appeared on the maps in the 17th century as an important part of the then sought Northern Sea Route and a rich whaling ground 49 Jan Mayen island was discovered in 1607 and become an important base of Dutch whalers The Dutchman Willem Barents discovered Bear Island and Svalbard 49 which was then used by Russian whalers called pomors The islands on the edge of the Norwegian Sea have been rapidly divided between nations During the peaks of whaling some 300 ships with 12 000 crew members were yearly visiting Svalbard 49 The first depth measurements of the Norwegian Sea were performed in 1773 by Constantine Phipps aboard HMS Racehorse as a part of his North Pole expedition 50 Systematic oceanographic research in the Norwegian Sea started in the late 19th century when declines in the yields of cod and herring off the Lofoten prompted the Norwegian government to investigate the matter 51 The zoologist Georg Ossian Sars and meteorologist Henrik Mohn persuaded the government in 1874 to send out a scientific expedition and between 1876 and 1878 they explored much of the sea aboard Voringen 52 The data obtained allowed Mohn to establish the first dynamic model of ocean currents which incorporated winds pressure differences sea water temperature and salinity and agreed well with later measurements 53 In 2019 deposits of iron copper zink and cobalt were found on the Mohn Ridge likely from hydrothermal vents 54 Navigation Edit HMS Sheffield during the winter convoy through the Norwegian Sea to Russia in 1941 Soviet nuclear submarine K 278 Komsomolets 1986 Until the 20th century the coasts of the Norwegian Sea were sparsely populated and therefore shipping in the sea was mostly focused on fishing whaling and occasional coastal transportation Since the late 19th century the Norwegian Coastal Express sea line has been established connecting the more densely populated south with the north of Norway by at least one trip a day The importance of shipping in the Norwegian Sea also increased with the expansion of the Russian and Soviet navies in the Barents Sea and development of international routes to the Atlantic through the Baltic Sea Kattegat Skagerrak and North Sea The Norwegian Sea is ice free and provides a direct route from the Atlantic to the Russian ports in the Arctic Murmansk Arkhangelsk and Kandalaksha which are directly linked to central Russia This route was extensively used for supplies during World War II of 811 US ships 720 reached Russian ports bringing some 4 million tonnes of cargo that included about 5 000 tanks and 7 000 aircraft The Allies lost 18 convoys and 89 merchant ships on this route 55 The major operations of the German Navy against the convoys included PQ 17 in July 1942 the Battle of the Barents Sea in December 1942 and the Battle of the North Cape in December 1943 and were carried out around the border between the Norwegian Sea and Barents Sea near the North Cape 55 Navigation across the Norwegian Sea declined after World War II and intensified only in the 1960s 70s with the expansion of the Soviet Northern Fleet which was reflected in major joint naval exercises of the Soviet Northern Baltic fleets in the Norwegian Sea The sea was the gateway for the Soviet Navy to the Atlantic Ocean and thus to the United States and the major Soviet port of Murmansk was just behind the border of the Norwegian and Barents Sea 56 The countermeasures by the NATO countries resulted in a significant naval presence in the Norwegian Sea and intense cat and mouse games between Soviet and NATO aircraft ships and especially submarines 57 A relic of the Cold War in the Norwegian Sea the Soviet nuclear submarine K 278 Komsomolets sank in 1989 southwest of Bear Island at the border of the Norwegian and Barents seas with radioactive material onboard that poses potential danger to flora and fauna 58 The Norwegian Sea is part of the Northern Sea Route for ships from European ports to Asia The travel distance from Rotterdam to Tokyo is 21 100 km 13 111 mi via the Suez Canal and only 14 100 km 8 761 mi through the Norwegian Sea Sea ice is a common problem in the Arctic seas but ice free conditions along the entire northern route were observed at the end of August 2008 59 Russia is planning to expand its offshore oil production in the Arctic which should increase the traffic of tankers through the Norwegian Sea to markets in Europe and America it is expected that the number of oil shipments through the northern Norwegian Sea will increase from 166 in 2002 to 615 in 2015 60 Map of the Langeled pipeline Oil and gas Edit The most important products of the Norwegian Sea are no longer fish but oil and especially gas found under the ocean floor 61 Norway started undersea oil production in 1993 followed by development of the Huldra gas field in 2001 62 The large depth and harsh waters of the Norwegian Sea pose significant technical challenges for offshore drilling 63 Whereas drilling at depths exceeding 500 metres has been conducted since 1995 only a few deep gas fields have been explored commercially The most important current project is Ormen Lange depth 800 1 100 m where gas production started in 2007 With reserves of 4 0 1011 m3 1 4 1013 cu ft it is the major Norwegian gas field It is connected to the Langeled pipeline currently the world s longest underwater pipeline and thus to a major European gas pipeline network 64 65 Several other gas fields are being developed As of 2019 there is an estimated 6 5 hm3 of crude oil in the Norwegian Sea with an expectation to increase oil production in the region up until 2025 A particular challenge is the Kristin field where the temperature is as high as 170 C and the gas pressure exceeds 900 bar 900 times the normal pressure 63 Further north are Norne and Snohvit In popular culture EditIn the popular fishing game Russian Fishing 4 Norwegian Sea is the newest map for fishing especially boat fishing 66 See also Edit Oceans portalList of seasReferences Edit a b c d Norwegian Sea Great Soviet Encyclopedia in Russian Norwegian Sea Encyclopaedia Britannica on line ICES 2007 p 1 Westerly storms warm Norway Archived 2018 09 29 at the Wayback Machine The Research Council of Norway Forskningsradet no 3 September 2012 Retrieved on 2013 03 21 Limits of Oceans and Seas 3rd edition PDF International Hydrographic Organization 1953 Archived from the original PDF on 8 October 2011 Retrieved 28 December 2020 a b c d Terje Thornes amp Oddvar Longva The origin of the coastal zone in Saetre 2007 pp 35 43 a b c Saetre 2007 pp 44 58 a b c d e f g h i j k Blindheim 1989 pp 366 382 Aken 2007 pp 119 124 Roald Saetre Driving forces in Saetre 2007 pp 44 58 a b Matti Seppala The Physical Geography of Fennoscandia Oxford University Press 2005 ISBN 0 19 924590 8 pp 121 141 Tyler 2003 pp 45 49 a b Tyler 2003 pp 115 116 ICES 2007 pp 2 4 Tyler 2003 pp 240 260 a b Aken 2007 pp 131 138 Skreslet amp NATO 2005 p 93 Ronald E Hester Roy M Harrison Biodiversity Under Threat Royal Society of Chemistry 2007 ISBN 0 85404 251 2 p 96 a b c Gerold Wefer Frank Lamy Fauzi Mantoura Marine Science Frontiers for Europe Springer 2003 ISBN 3 540 40168 7 pp 32 35 Schaefer 2001 pp 10 17 Kieran Mulvaney At the Ends of the Earth A History of the Polar Regions Iceland Press 2001 ISBN 1 55963 908 3 p 23 a b c d e f Skreslet amp NATO 2005 pp 103 114 a b Andrea Schroder Ritzrau et al Distribution export and alteration of plankton in the Norwegian Sea Fossiliziable Schaefer 2001 pp 81 104 a b c d e f g ICES 2007 pp 5 8 a b Blindheim 1989 pp 382 401 Olav Schram Stokke Governing High Seas Fisheries The Interplay of Global and Regional regime Oxford University Press 2001 ISBN 0 19 829949 4 pp 241 255 a b Gene S Helfman Fish Conservation A Guide to Understanding and Restoring Global Aquatic Biodiversity and Fishery Resources Iceland Press 2007 ISBN 1 55963 595 9 pp 321 323 National Research Council U S Committee on Ecosystem Management for Sustainable Marine Fisheries Sustaining Marine Fisheries National Academies Press 1999 ISBN 0 309 05526 1 p 46 Erich Hoyt Marine Protected Areas for Whales Dolphins and Porpoises Earthscan 2005 ISBN 1 84407 063 8 pp 120 128 Klinowska 1991 p 138 Norwegian minke whaling the Norwegian Ministry of Foreign Affairs norway org uk a b Johnson 1982 pp 95 101 Klinowska 1991 p 320 Simon Jennings et al Marine Fisheries Ecology Blackwell Publishing 2001 ISBN 0 632 05098 5 p 297 a b c Alf Hakon Noel The Performance of Exclusive Economic Zones The Case of Norway in Syma A Ebbin et al A Sea Change The Exclusive Economic Zone and Governance Institutions for Living Marine Resources Springer 2005 ISBN 1 4020 3132 7 Archaeology of Viking Age Faroe Islands Projekt Forlǫg in Czech 2 June 2016 Retrieved 2020 12 09 Tyler 2003 p 434 Tim Denis Smith Scaling Fisheries The Science of Measuring the Effects of Fishing 1855 1955 Cambridge University Press 1994 ISBN 0 521 39032 X pp 10 15 EU still far from phasing out overfishing by 2020 Oceana Europe Retrieved 2020 12 07 EU Norway agreement the worst outcome for fish stocks in ten years Our Fish Retrieved 2020 12 07 Depleted fish stocks can t wait The EU and Norway need to commit to ending overfishing now ǀ View euronews 2019 12 02 Retrieved 2020 12 07 Elliott Stuart 24 January 2023 Norway plans to include more Barents Sea Norwegian Sea blocks in new APA round www spglobal com Retrieved 16 February 2023 a b Richards 2006 pp 589 596 Richards 2006 pp 574 580 Octopus in E Smedley et al Eds Encyclopaedia metropolitana or universal dictionary of knowledge in 1845 pp 326 330 Terry Glavin The Sixth Extinction Journeys Among the Lost and Left Behind Macmillan 2007 ISBN 0 312 36231 5 p 149 The Merriam Webster new book of word histories 1991 ISBN 0 87779 603 3 p 300 Tom Kopel Ebb and Flow Tides and Life on Our Once and Future Planet Dundurn Press 2007 ISBN 1 55002 726 3 pp 76 79 a b c Neil Kent The Soul of the North A Social Architectural and Cultural History of the Nordic Countries 1700 1940 Reaktion Books 2001 ISBN 1 86189 067 2 pp 300 302 Colin Summerhayes The exploration of the sea floor in Margaret Deacon et al Eds Understanding the oceans a century of ocean exploration Routledge 2001 ISBN 1 85728 705 3 p 93 Mills 2001 pp 41 43 Mills 2001 pp 44 47 Mills 2001 pp 50 53 Andersen Ina 14 June 2019 Minaleralfunnet pa havbunnen inneholder mye kobber Tu no in Norwegian Teknisk Ukeblad a b Edward L Killham The Nordic Way A Path to Baltic Equilibrium Howells House 1993 ISBN 0 929590 12 0 p 106 Joel J Sokolsky Seapower in the Nuclear Age The United States Navy and NATO 1949 80 Taylor amp Francis 1991 ISBN 0 415 00806 9 pp 83 87 Olav Riste NATO s Northern Front Line in 1980s in Olav Njolstad The Last Decade of the Cold War From Conflict Escalation to Conflict Transformation Routledge 2004 ISBN 0 7146 8539 9 pp 360 371 Hugh D Livingston Marine Radioactivity Elsevier 2004 ISBN 0 08 043714 1 p 92 Seidler Christoph August 27 2008 Northeast and the Northwest Passage ice free for the first time at the same time Der Spiegel Retrieved July 21 2011 Leichenko Robin M amp Karen L O Brien Environmental Change and Globalization ISBN 0 19 517732 0 p 99 Jerome D Davis Changing World of Oil An Analysis of Corporate Change and Adaptation Ashgate Publishing 2006 ISBN 0 7546 4178 3 p 139 Ann Genova The Politics of the Global Oil Industry Greenwood Publishing Group 2005 ISBN 0 275 98400 1 pp 202 209 a b Geo ExPro November 2004 Kristin A Tough Lady Archived 2011 07 11 at the Wayback Machine pdf Country Analysis Briefs Norway Energy Information Administration Moskwa Wojciech September 13 2007 Norway s Ormen Lange gas starts flowing to Britain Reuters Retrieved March 30 2022 Russian Fishing 4 Norwegian Sea Trailer News Russian Fishing 4 Retrieved 16 February 2023 Bibliography Editvan Aken Hendrik Mattheus 2007 The Oceanic Thermohaline Circulation An Introduction Springer ISBN 978 0 387 36637 1 Blindheim Johan 1989 Ecological Features of the Norwegian Sea In Louis Rene Rey et al eds Proceedings of the Sixth Conference of the Comite arctique international 13 15 May 1985 Brill Publishers pp 366 401 ISBN 90 04 08281 6 International Council for the Exploration of the Sea 2007 The Barents Sea and the Norwegian Sea PDF ICES Advice 2007 Vol 3 Archived from the original on 2011 09 27 a href Template Cite book html title Template Cite book cite book a CS1 maint bot original URL status unknown link Johnson Arne Odd 1982 The History of Modern Whaling C Hurst amp Co Publishers ISBN 0 905838 23 8 Klinowska Margaret ed 1991 Dolphins Porpoises and Whales of the World The IUCN Red Data Book ISBN 2 88032 936 1 Mills Eric L 2001 Mathematics in Neptune s Garden In Helen M Rozwadowski amp David K van Keuren ed The Machine in Neptune s Garden Historical Perspectives on Technology and the Marine Environment Science History Publications USA ISBN 0 88135 372 8 Richards John F 2006 The Unending Frontier An Environmental History of the Early Modern World University of California Press ISBN 0 520 24678 0 Saetre Roald ed 2007 The Norwegian Coastal Current Oceanography and Climate Trondheim Tapir Academic Press ISBN 978 82 519 2184 8 Schaefer Priska 2001 The Northern North Atlantic A Changing Environment Springer ISBN 3 540 67231 1 Skreslet Stig North Atlantic Treaty Organization 2005 Jan Mayen Iceland in Scientific Focus Springer ISBN 1 4020 2956 X Tyler Paul A 2003 Ecosystems of the Deep Oceans Ecosystems of the World Elsevier ISBN 0 444 82619 X External links EditDickson Henry Newton 1911 Norwegian Sea Encyclopaedia Britannica Vol 19 11th ed p 818 Media related to Norwegian Sea at Wikimedia Commons Retrieved from https en wikipedia org w index php title Norwegian Sea amp oldid 1139619140, wikipedia, wiki, book, books, library,

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