Migration

movement of animals from place to place, usually seasonal
(Redirected from Migratory)
For people see Human migration; for data see Data migration.

Migration is when animals move on a regular cycle. For example, caribou in the Arctic go south in winter and return in summer when it is warmer. Many birds migrate, such as geese and storks.

Wildebeest crossing river in East Africa

Migration is the travelling of long distances in search of a new habitat. The trigger for the migration may be local climate, local availability of food, or the season of the year. To be counted as a true migration, and not just a local dispersal, the movement should be an annual or seasonal event.

Many birds fly to warmer places for the winter, as do some insects such as the migratory locust. Young Atlantic salmon leave the river of their birth when they have reached a few inches (cm) in size.[1]

Many species in the sea have a daily migration. Plankton go up for the day where there is light, and down at night, where they are less easy to find. The many species which feed on them follow them up and down.

Migration is an evolutionary force. This is because it is a major source of natural selection. The success of migratory animals to make the journey is usually needed for them to reproduce.

Many parts of the world have a strongly seasonal climate. In order to survive, many species need to breed in one place and, later, eat in another place. The simplest example is the African herbivores, who follow the growth of grass in East Africa. This region has seasonal rainfall, and so it has seasonal growth of grass. Their predators follow them.[1]

Bird migration

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Examples of long-distance bird migration routes

Bird migration is the regular seasonal movement, usually north and south along a 'flyway', between breeding and wintering grounds. Many species of bird migrate. Many birds die when they are migrating, and is mainly to get food. It occurs mostly in the northern hemisphere, where birds are funnelled on to specific routes by natural barriers such as the Mediterranean Sea or the Caribbean Sea.

Distances

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The Arctic tern holds the long-distance migration record for birds. It flies between Arctic breeding grounds and the Antarctic each year. Albatrosses circle the earth, flying over the southern oceans. The Manx shearwater migrates 14,000 km (8,700 mi) between its northern breeding grounds and the southern ocean. Shorter migrations are common, including altitudinal migrations up and down mountains like the Andes and Himalayas.


Since the distance that some birds travel on migration can be enormous,[2] why such huge distances? Migration is useful for the birds, because the seasonal differences are to the birds' advantage. So far as is known, migration instincts are inherited: the birds cannot make a personal choice in the matter. All the same, in some species not all migrate. There is a cost to migration in the number of birds which die en route. There is an advantage only if the birds which migrate have a better chance of leaving descendants. Studies of migration have been done since the 18th century.[3] There is still much we do not know about it.

Historically, bird migration would have started when the continents were close together. It might have started in the Upper Cretaceous or the Palaeocene. Then. as the continents drifted apart, the bird migrations got longer and longer. That makes sense, and probably is what happened. There is no direct evidence.

How do they do it?

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Biomagnetism is part of the answer. There are crystals of magnetite which occur in many birds (and some other organisms).[4] There is also a chemical basis for cellular sensitivity to electric and magnetic fields (galvanotaxis).[5]

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References

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  1. 1.0 1.1 David Attenborough (1990). The trials of life. London: Collins / BBC Books. p. 123. ISBN 0002199408.
  2. Gill, Frank 1995. Ornithology. New York: WH Freeman. ISBN 0-7167-2415-4
  3. Greenwood, Jeremy J. D. (2007). "Citizens, science and bird conservation". Journal of Ornithology. 148 (Supplement 1): S77–S124. doi:10.1007/s10336-007-0239-9. S2CID 21914046.
  4. Kirschvink, J L; Walker, M.M; Diebel, C.E (2001). "Magnetite-based magnetoreception". Current Opinion in Neurobiology. 11 (4): 462–7. doi:10.1016/s0959-4388(00)00235-x. PMID 11502393. S2CID 16073105.
  5. Nakajima, Ken-ichi; Zhu, Kan; Sun, Yao-Hui; Hegyi, Bence; Zeng, Qunli; Murphy, Christopher J; Small, J Victor; Chen-Izu, Ye; Izumiya, Yoshihiro; Penninger, Josef M; Zhao, Min (2015). "KCNJ15/Kir4.2 couples with polyamines to sense weak extracellular electric fields in galvanotaxis". Nature Communications. 6: 8532. Bibcode:2015NatCo...6.8532N. doi:10.1038/ncomms9532. PMC 4603535. PMID 26449415. Taken together these data suggest a previously unknown two-molecule sensing mechanism in which KCNJ15/Kir4.2 couples with polyamines in sensing weak electric fields.
  • Baker R.R. 1978. The evolutionary ecology of animal migration. New York: Holmes & Meyer.