Bird

For other uses, see Bird (disambiguation).

"Aves" and "Avifauna" redirect here. For other uses, see Aves (disambiguation) and Avifauna (disambiguation).

Birds (Aves), also known as avian dinosaurs,[3] are a group of endothermic vertebrates, characterised by feathers, toothless beaked jaws, the laying of hard-shelled eggs, a high metabolic rate, a four-chambered heart, and a lightweight but strong skeleton. Birds live worldwide and range in size from the 5 cm (2 in) bee hummingbird to the 2.75 m (9 ft) ostrich. They rank as the class of tetrapods with the most living species, at approximately ten thousand, with more than half of these being passerines, sometimes known as perching birds or, less accurately, as songbirds.

The fossil record indicates that birds are the last surviving group of dinosaurs, having evolved from feathered ancestors within the theropod group of saurischian dinosaurs. True birds first appeared during the Cretaceous period, around 100 million years ago.[4] DNA-based evidence finds that birds diversified dramatically around the time of the Cretaceous–Palaeogene extinction event that killed off all other dinosaurs. Birds, especially those in the southern continents, survived this event and then migrated to other parts of the world while diversifying during periods of global cooling.[5] Primitive bird-like dinosaurs that lie outside class Aves proper, in the broader group Avialae, have been found dating back to the mid-Jurassic period.[1] Many of these early "stem-birds", such as Archaeopteryx, were not yet capable of fully powered flight, and many retained primitive characteristics like toothy jaws in place of beaks, and long bony tails.[1][6]

Birds have wings which are more or less developed depending on the species; the only known groups without wings are the extinct moas and elephant birds. Wings, which evolved from forelimbs, gave birds the ability to fly, although further speciation has led to the loss of flight in flightless birds, including ratites, penguins, and diverse endemic island species of birds. The digestive and respiratory systems of birds are also uniquely adapted for flight. Some bird species of aquatic environments, particularly the aforementioned flightless penguins, and also members of the duck family, have further evolved for swimming. Birds, specifically Darwin's finches, played an important part in the inception of Darwin's theory of evolution by natural selection.

Some birds, especially corvids and parrots, are among the most intelligent animals; several bird species make and use tools, and many social species pass on knowledge across generations, which is considered a form of culture. Many species annually migrate great distances. Birds are social, communicating with visual signals, calls, and bird songs, and participating in such social behaviours as cooperative breeding and hunting, flocking, and mobbing of predators. The vast majority of bird species are socially monogamous (referring to social living arrangement, distinct from genetic monogamy), usually for one breeding season at a time, sometimes for years, but rarely for life. Other species have breeding systems that are polygynous (arrangement of one male with many females) or, rarely, polyandrous (arrangement of one female with many males). Birds produce offspring by laying eggs which are fertilised through sexual reproduction. They are usually laid in a nest and incubated by the parents. Most birds have an extended period of parental care after hatching. Some birds, such as hens, lay eggs even when not fertilised, though unfertilised eggs do not produce offspring.

Many species of birds are economically important. Domesticated and undomesticated birds (poultry and game) are important sources of eggs, meat, and feathers. Songbirds, parrots, and other species are popular as pets. Guano (bird excrement) is harvested for use as a fertiliser. Birds prominently figure throughout human culture. About 120–130 species have become extinct due to human activity since the 17th century, and hundreds more before then. Human activity threatens about 1,200 bird species with extinction, though efforts are underway to protect them. Recreational birdwatching is an important part of the ecotourism industry.

Evolution and classification

Main article: Evolution of birds
 Slab of stone with fossil bones and feather impressions
Archaeopteryx lithographica is often considered the oldest known true bird.

The first classification of birds was developed by Francis Willughby and John Ray in their 1676 volume Ornithologiae.[7] Carl Linnaeus modified that work in 1758 to devise the taxonomic classification system currently in use.[8] Birds are categorised as the biological class Aves in Linnaean taxonomy. Phylogenetic taxonomy places Aves in the dinosaur clade Theropoda.[9]

Definition

Aves and a sister group, the clade Crocodilia, contain the only living representatives of the reptile clade Archosauria. During the late 1990s, Aves was most commonly defined phylogenetically as all descendants of the most recent common ancestor of modern birds and Archaeopteryx lithographica.[10] However, an earlier definition proposed by Jacques Gauthier gained wide currency in the 21st century, and is used by many scientists including adherents of the Phylocode system. Gauthier defined Aves to include only the crown group of the set of modern birds. This was done by excluding most groups known only from fossils, and assigning them, instead, to the Avialae,[11] in part to avoid the uncertainties about the placement of Archaeopteryx in relation to animals traditionally thought of as theropod dinosaurs.

Gauthier[12] identified four conflicting ways of defining the term "Aves", which is a problem because the same biological name is being used four different ways. Gauthier proposed a solution, number 4 below, which is to reserve the term Aves only for the crown group, the last common ancestor of all living birds and all of its descendants. He assigned other names to the other groups.




Crocodiles



Birds




Turtles




Lizards (including snakes)


The birds' phylogenetic relationships to major living reptile groups.
  1. Aves can mean those advanced archosaurs with feathers (alternately Avifilopluma)
  2. Aves can mean those that fly (alternately Avialae)
  3. Aves can mean all reptiles closer to birds than to crocodiles (alternately Avemetatarsalia [=Panaves])
  4. Aves can mean the last common ancestor of all the currently living birds and all of its descendants (a "crown group"). (alternately Neornithes)

Under the fourth definition Archaeopteryx is an avialan, and not a member of Aves. Gauthier's proposals have been adopted by many researchers in the field of palaeontology and bird evolution, though the exact definitions applied have been inconsistent. Avialae, initially proposed to replace the traditional fossil content of Aves, is often used synonymously with the vernacular term "bird" by these researchers.[13]

Most researchers define Avialae as branch-based clade, though definitions vary. Many authors have used a definition similar to "all theropods closer to birds than to Deinonychus."[14][15] Avialae is also occasionally defined as an apomorphy-based clade (that is, one based on physical characteristics). Jacques Gauthier, who named Avialae in 1986, re-defined it in 2001 as all dinosaurs that possessed feathered wings used in flapping flight, and the birds that descended from them.[12][16]

Dinosaurs and the origin of birds

Main article: Origin of birds
Paraves

Scansoriopterygidae




Eosinopteryx


Eumaniraptora

Jinfengopteryx



Aurornis



Dromaeosauridae



Troodontidae



Avialae





Cladogram following the results of a phylogenetic study by Cau et al., 2015.[17]

Based on fossil and biological evidence, most scientists accept that birds are a specialised subgroup of theropod dinosaurs,[18] and more specifically, they are members of Maniraptora, a group of theropods which includes dromaeosaurs and oviraptorids, among others.[19] As scientists have discovered more theropods closely related to birds, the previously clear distinction between non-birds and birds has become blurred. Recent discoveries in the Liaoning Province of northeast China, which demonstrate many small theropod feathered dinosaurs, contribute to this ambiguity.[20][21][22]

The consensus view in contemporary palaeontology is that the flying theropods, or avialans, are the closest relatives of the deinonychosaurs, which include dromaeosaurids and troodontids.[23] Together, these form a group called Paraves. Some basal members of this group, such as Microraptor, have features which may have enabled them to glide or fly. The most basal deinonychosaurs were very small. This evidence raises the possibility that the ancestor of all paravians may have been arboreal, have been able to glide, or both.[24][25] Unlike Archaeopteryx and the non-avialan feathered dinosaurs, who primarily ate meat, recent studies suggest that the first avialans were omnivores.[26]

 White slab of rock left with cracks and impression of bird feathers and bone, including long paired tail feathers
Confuciusornis sanctus, a Cretaceous bird from China

The Late Jurassic Archaeopteryx is well known as one of the first transitional fossils to be found, and it provided support for the theory of evolution in the late 19th century. Archaeopteryx was the first fossil to display both clearly traditional reptilian characteristics: teeth, clawed fingers, and a long, lizard-like tail, as well as wings with flight feathers similar to those of modern birds. It is not considered a direct ancestor of birds, though it is possibly closely related to the true ancestor.[27]

Early evolution

Avialae

Anchiornis




Archaeopteryx




Xiaotingia




Rahonavis





Jeholornis



Jixiangornis



Euavialae

Balaur


Avebrevicauda

Zhongjianornis




Sapeornis


Pygostylia

Confuciusornithiformes





Protopteryx



Pengornis




Ornithothoraces












Cladogram following the results of a phylogenetic study by Cau et al., 2015.[17]

The earliest known avialan fossils come from the Tiaojishan Formation of China, which has been dated to the late Jurassic period (Oxfordian stage), about 160 million years ago.[13] The avialan species from this time period include Anchiornis huxleyi, Xiaotingia zhengi, and Aurornis xui. The well-known early avialan, Archaeopteryx, dates from slightly later Jurassic rocks (about 155 million years old) from Germany. Many of these early avialans shared unusual anatomical features that may be ancestral to modern birds, but were later lost during bird evolution. These features include enlarged claws on the second toe which may have been held clear of the ground in life, and long feathers or "hind wings" covering the hind limbs and feet, which may have been used in aerial maneuvering.[28]

Avialans diversified into a wide variety of forms during the Cretaceous Period.[29] Many groups retained primitive characteristics, such as clawed wings and teeth, though the latter were lost independently in a number of avialan groups, including modern birds (Aves). While the earliest forms, such as Archaeopteryx and Jeholornis, retained the long bony tails of their ancestors,[29] the tails of more advanced avialans were shortened with the advent of the pygostyle bone in the group Pygostylia. In the late Cretaceous, around 95 million years ago, the ancestor of all modern birds also evolved a better sense of smell.[30]

Early diversity of bird ancestors

Ornithothoraces

Enantiornithes


Euornithes

Archaeorhynchus


Ornithuromorpha

Patagopteryx



Vorona




Schizooura




Hongshanornithidae




Jianchangornis




Songlingornithidae




Gansus




Apsaravis


Ornithurae

Hesperornithes




Ichthyornis




Vegavis



Aves














Mesozoic bird phylogeny simplified after Wang et al., 2015's phylogenetic analysis.[31]

The first large, diverse lineage of short-tailed avialans to evolve were the enantiornithes, or "opposite birds", so named because the construction of their shoulder bones was in reverse to that of modern birds. Enantiornithes occupied a wide array of ecological niches, from sand-probing shorebirds and fish-eaters to tree-dwelling forms and seed-eaters. While they were the dominant group of avialans during the Cretaceous period, enantiornithes became extinct along with many other dinosaur groups at the end of the Mesozoic era.[29]

Many species of the second major avialan lineage to diversify, the Euornithes (meaning "true birds", because they include the ancestors of modern birds), were semi-aquatic and specialised in eating fish and other small aquatic organisms. Unlike the enantiornithes, which dominated land-based and arboreal habitats, most early euornithes lacked perching adaptations and seem to have included shorebird-like species, waders, and swimming and diving species. The later included the superficially gull-like Ichthyornis,[32] the Hesperornithiformes, which became so well adapted to hunting fish in marine environments that they lost the ability to fly and became primarily aquatic.[29] The early euornithes also saw the development of many traits associated with modern birds, like strongly keeled breastbones, toothless, beaked portions of their jaws (though most non-avian euornithes retained teeth in other parts of the jaws).[33] Euornithes also included the first avialans to develop true pygostyle and a fully mobile fan of tail feathers,[34] which may have replaced the "hind wing" as the primary mode of aerial maneuverability and braking in flight.[28]

Diversification of modern birds

Aves  
Palaeognathae 

Struthioniformes



Tinamiformes



 Neognathae 
 

Other birds (Neoaves)


Galloanserae 

Anseriformes



Galliformes





Basal divergences of modern birds
based on Sibley-Ahlquist taxonomy

All modern birds lie within the crown group Aves (alternately Neornithes), which has two subdivisions: the Palaeognathae, which includes the flightless ratites (such as the ostriches) and the weak-flying tinamous, and the extremely diverse Neognathae, containing all other birds.[9] These two subdivisions are often given the rank of superorder,[35] although Livezey and Zusi assigned them "cohort" rank.[9] Depending on the taxonomic viewpoint, the number of known living bird species varies anywhere from 9,800[36] to 10,050.[37]

Due largely to the discovery of Vegavis, a late Cretaceous neognath member of the duck lineage, Aves is known to have split into several modern lineages by the end of the Mesozoic era.[38] Studies using a "morphological clock" analysis have estimated that the actual origin of modern birds probably occurred slightly earlier than the earliest known fossils, during the mid-Cretaceous period.[1]

The earliest divergence within the Neognathes was that of the Galloanserae, the superorder containing the Anseriformes (ducks, geese, swans and screamers) and the Galliformes (the pheasants, grouse, and their allies, together with the mound builders and the guans and their allies). The earliest fossil remains of true birds come from the possible galliform Austinornis lentus, dated to about 85 million years ago,[39] but the dates for the actual splits are much debated by scientists. The Aves are agreed to have evolved in the Cretaceous, and the split between the Galloanseri from other Neognathes occurred before the Cretaceous–Palaeogene extinction event, but there are different opinions about whether the radiation of the remaining Neognathes occurred before or after the extinction of the other dinosaurs.[40] This disagreement is in part caused by a divergence in the evidence; molecular dating suggests a Cretaceous radiation, while fossil evidence supports a Cenozoic radiation. Attempts to reconcile the molecular and fossil evidence have proved controversial,[40][41] but recent results show that all the extant groups of birds originated from only a small handful of species that survived the Cretaceous–Palaeogene extinction.[42]

Classification of bird orders

See also: List of birds

Cladogram of modern bird relationships based on Jarvis, E.D. et al. (2014)[43] with some clade names after Yury, T. et al. (2013).[44]

Aves
Palaeognathae

Struthioniformes (ostriches)


Notopalaeognathae

Rheiformes (rheas)





Dinornithiformes (moas)




Lithornithiformes



Tinamiformes (tinamous)




Novaeratitae

Casuariiformes (emus & cassowaries)




Apterygiformes (kiwis)



Aepyornithiformes (elephant birds)







Neognathae
Galloanserae

Galliformes (chicken, grouse, turkeys, etc.)


Odontoanserae

Pelagornithidae


Anserimorphae

Gastornithiformes



Anseriformes (ducks, geese, and swans)





Neoaves
Columbea
Mirandornithes

Phoenicopteriformes (flamingos)



Podicipediformes (grebes)



Columbimorphae

Columbiformes (pigeons and dodos)




Mesitornithiformes (mesites)



Pteroclidiformes (sandgrouses)





Passerea


Cypselomorphae (hummingbirds, swifts)


Otidimorphae

Cuculiformes (cuckoos)




Otidiformes (bustards)



Musophagiformes (turacos)








Opisthocomiformes (hoatzin)


Cursorimorphae

Gruiformes (rails and cranes)



Charadriiformes (gulls, auks, shorebirds, waders)







Aequornithes (loons, penguins, herons, pelicans, storks, etc)


Eurypygimorphae

Eurypygiformes (sunbittern, kagu)



Phaethontiformes (tropicbirds)




Telluraves
Afroaves
Accipitrimorphae

Cathartiformes (condors and New World vultures)



Accipitriformes (hawks, eagles, Old World vultures etc.)





Strigiformes (owls)


Coraciimorphae

Coliiformes (mousebirds)


Eucavitaves

Leptosomatiformes (cuckoo roller)


Cavitaves

Trogoniformes (trogons)


Picocoraciae

Bucerotiformes (hornbills, hoopoe and wood hoopoes)




Coraciformes (kingfishers etc.)



Piciformes (woodpeckers, toucans etc.)









Australaves

Cariamiformes (seriemas, terror birds etc)


Eufalconimorphae

Falconiformes (falcons)


Psittacopasserae

Psittaciformes (parrots)



Passeriformes (songbirds and kin)












The classification of birds is a contentious issue. Sibley and Ahlquist's Phylogeny and Classification of Birds (1990) is a landmark work on the classification of birds,[45] although it is frequently debated and constantly revised. Most evidence seems to suggest the assignment of orders is accurate,[46] but scientists disagree about the relationships between the orders themselves; evidence from modern bird anatomy, fossils and DNA have all been brought to bear on the problem, but no strong consensus has emerged. More recently, new fossil and molecular evidence is providing an increasingly clear picture of the evolution of modern bird orders. The most recent effort is drawn above and is based on whole genome sequencing of 48 representative species.[43]

Distribution

 small bird withpale belly and breast and patterned wing and head stands on concrete
The range of the house sparrow has expanded dramatically due to human activities.[47]

Birds live and breed in most terrestrial habitats and on all seven continents, reaching their southern extreme in the snow petrel's breeding colonies up to 440 kilometres (270 mi) inland in Antarctica.[48] The highest bird diversity occurs in tropical regions. It was earlier thought that this high diversity was the result of higher speciation rates in the tropics, however recent studies found higher speciation rates in the high latitudes that were offset by greater extinction rates than in the tropics.[49] Several families of birds have adapted to life both on the world's oceans and in them, with some seabird species coming ashore only to breed[50] and some penguins have been recorded diving up to 300 metres (980 ft).[51]

Many bird species have established breeding populations in areas to which they have been introduced by humans. Some of these introductions have been deliberate; the ring-necked pheasant, for example, has been introduced around the world as a game bird.[52] Others have been accidental, such as the establishment of wild monk parakeets in several North American cities after their escape from captivity.[53] Some species, including cattle egret,[54] yellow-headed caracara[55] and galah,[56] have spread naturally far beyond their original ranges as agricultural practices created suitable new habitat.

Anatomy and physiology

Main articles: Bird anatomy and Bird vision
See also: Egg tooth
External anatomy of a bird (example: yellow-wattled lapwing): 1 Beak, 2 Head, 3 Iris, 4 Pupil, 5 Mantle, 6 Lesser coverts, 7 Scapulars, 8 Median coverts, 9 Tertials, 10 Rump, 11 Primaries, 12 Vent, 13 Thigh, 14 Tibio-tarsal articulation, 15 Tarsus, 16 Foot, 17 Tibia, 18 Belly, 19 Flanks, 20 Breast, 21 Throat, 22 Wattle, 23 Eyestripe

Compared with other vertebrates, birds have a body plan that shows many unusual adaptations, mostly to facilitate flight.

Skeletal system

The skeleton consists of very lightweight bones. They have large air-filled cavities (called pneumatic cavities) which connect with the respiratory system.[57] The skull bones in adults are fused and do not show cranial sutures.[58] The orbits are large and separated by a bony septum. The spine has cervical, thoracic, lumbar and caudal regions with the number of cervical (neck) vertebrae highly variable and especially flexible, but movement is reduced in the anterior thoracic vertebrae and absent in the later vertebrae.[59] The last few are fused with the pelvis to form the synsacrum.[58] The ribs are flattened and the sternum is keeled for the attachment of flight muscles except in the flightless bird orders. The forelimbs are modified into wings.[60]

Excretory system

Like the reptiles, birds are primarily uricotelic, that is, their kidneys extract nitrogenous waste from their bloodstream and excrete it as uric acid instead of urea or ammonia through the ureters into the intestine. Birds do not have a urinary bladder or external urethral opening and (with exception of the ostrich) uric acid is excreted along with faeces as a semisolid waste.[61][62][63] However, birds such as hummingbirds can be facultatively ammonotelic, excreting most of the nitrogenous wastes as ammonia.[64] They also excrete creatine, rather than creatinine like mammals.[58] This material, as well as the output of the intestines, emerges from the bird's cloaca.[65][66] The cloaca is a multi-purpose opening: waste is expelled through it, most birds mate by joining cloaca, and females lay eggs from it. In addition, many species of birds regurgitate pellets.[67] Males within Palaeognathae (with the exception of the kiwis), the Anseriformes (with the exception of screamers), and in rudimentary forms in Galliformes (but fully developed in Cracidae) possess a penis, which is never present in Neoaves.[68][69] The length is thought to be related to sperm competition.[70] When not copulating, it is hidden within the proctodeum compartment within the cloaca, just inside the vent. The digestive system of birds is unique, with a crop for storage and a gizzard that contains swallowed stones for grinding food to compensate for the lack of teeth.[71] Most birds are highly adapted for rapid digestion to aid with flight.[72] Some migratory birds have adapted to use protein from many parts of their bodies, including protein from the intestines, as additional energy during migration.[73]

Respiratory and circulatory systems

Birds have one of the most complex respiratory systems of all animal groups.[58] Upon inhalation, 75% of the fresh air bypasses the lungs and flows directly into a posterior air sac which extends from the lungs and connects with air spaces in the bones and fills them with air. The other 25% of the air goes directly into the lungs. When the bird exhales, the used air flows out of the lung and the stored fresh air from the posterior air sac is simultaneously forced into the lungs. Thus, a bird's lungs receive a constant supply of fresh air during both inhalation and exhalation.[74] Sound production is achieved using the syrinx, a muscular chamber incorporating multiple tympanic membranes which diverges from the lower end of the trachea;[75] the trachea being elongated in some species, increasing the volume of vocalisations and the perception of the bird's size.[76]

In birds, the main arteries taking blood away from the heart originate from the right aortic arch (or pharyngeal arch), unlike in the mammals where the left aortic arch forms this part of the aorta.[58] The postcava receives blood from the limbs via the renal portal system. Unlike in mammals, the circulating red blood cells in birds retain their nucleus.[77]

Heart type and features

The avian circulatory system is driven by a four-chambered, myogenic heart contained in a fibrous pericardial sac. This pericardial sac is filled with a serous fluid for lubrication.[78] The heart itself is divided into a right and left half, each with an atrium and ventricle. The atrium and ventricles of each side are separated by atrioventricular valves which prevent back flow from one chamber to the next during contraction. Being myogenic, the heart's pace is maintained by pacemaker cells found in the sinoatrial node, located on the right atrium. The sinoatrial node uses calcium to cause a depolarising signal transduction pathway from the atrium through right and left atrioventricular bundle which communicates contraction to the ventricles. The avian heart also consists of muscular arches that are made up of thick bundles of muscular layers. Much like a mammalian heart, the avian heart is composed of endocardial, myocardial and epicardial layers.[78] The atrium walls tend to be thinner than the ventricle walls, due to the intense ventricular contraction used to pump oxygenated blood throughout the body. Avian hearts are generally larger than mammalian hearts when compared to body mass. This adaptation allows more blood to be pumped to meet the high metabolic need associated with flight.[79]

Organisation

Birds have a very efficient system for diffusing oxygen into the blood; birds have a ten times greater surface area to gas exchange volume than mammals. As a result, birds have more blood in their capillaries per unit of volume of lung than a mammal.[79] The arteries are composed of thick elastic muscles to withstand the pressure of the ventricular constriction, and become more rigid as they move away from the heart. Blood moves through the arteries, which undergo vasoconstriction, and into arterioles which act as a transportation system to distribute primarily oxygen as well as nutrients to all tissues of the body.[80] As the arterioles move away from the heart and into individual organs and tissues they are further divided to increase surface area and slow blood flow. Travelling through the arterioles blood moves into the capillaries where gas exchange can occur. Capillaries are organized into capillary beds in tissues, it is here that blood exchanges oxygen for carbon dioxide waste. In the capillary beds blood flow is slowed to allow maximum diffusion of oxygen into the tissues. Once the blood has become deoxygenated it travels through venules then veins and back to the heart. Veins, unlike arteries, are thin and rigid as they do not need to withstand extreme pressure. As blood travels through the venules to the veins a funneling occurs called vasodilation bringing blood back to the heart.[80] Once the blood reaches the heart it moves first into the right atrium, then the right ventricle to be pumped through the lungs for further gas exchange of carbon dioxide waste for oxygen. Oxygenated blood then flows from the lungs through the left atrium to the left ventricle where it is pumped out to the body.

The nictitating membrane as it covers the eye of a masked lapwing

Nervous system

The nervous system is large relative to the bird's size.[58] The most developed part of the brain is the one that controls the flight-related functions, while the cerebellum coordinates movement and the cerebrum controls behaviour patterns, navigation, mating and nest building. Most birds have a poor sense of smell with notable exceptions including kiwis,[81] New World vultures[82] and tubenoses.[83] The avian visual system is usually highly developed. Water birds have special flexible lenses, allowing accommodation for vision in air and water.[58] Some species also have dual fovea. Birds are tetrachromatic, possessing ultraviolet (UV) sensitive cone cells in the eye as well as green, red and blue ones.[84] This allows them to perceive ultraviolet light, which is involved in courtship. Birds have specialised light-sensing cells deep in their brains that respond to light without input from eyes or other sensory neurons. These photo-receptive cells in the hypothalamus are involved in detecting the longer days of spring, and thus regulate breeding activities.

Many birds show plumage patterns in ultraviolet that are invisible to the human eye; some birds whose sexes appear similar to the naked eye are distinguished by the presence of ultraviolet reflective patches on their feathers. Male blue tits have an ultraviolet reflective crown patch which is displayed in courtship by posturing and raising of their nape feathers.[85] Ultraviolet light is also used in foraging—kestrels have been shown to search for prey by detecting the UV reflective urine trail marks left on the ground by rodents.[86] The eyelids of a bird are not used in blinking. Instead the eye is lubricated by the nictitating membrane, a third eyelid that moves horizontally.[87] The nictitating membrane also covers the eye and acts as a contact lens in many aquatic birds.[58] The bird retina has a fan shaped blood supply system called the pecten.[58] Most birds cannot move their eyes, although there are exceptions, such as the great cormorant.[88] Birds with eyes on the sides of their heads have a wide visual field, while birds with eyes on the front of their heads, such as owls, have binocular vision and can estimate the depth of field.[89] The avian ear lacks external pinnae but is covered by feathers, although in some birds, such as the Asio, Bubo and Otus owls, these feathers form tufts which resemble ears. The inner ear has a cochlea, but it is not spiral as in mammals.[90]

Defence and intraspecific combat

A few species are able to use chemical defences against predators; some Procellariiformes can eject an unpleasant oil against an aggressor,[91] and some species of pitohuis from New Guinea have a powerful neurotoxin in their skin and feathers.[92]

A dearth of field observations limit our knowledge, but intraspecific conflicts are known to sometimes result in injury or death.[93] The screamers (Anhimidae), some jacanas (Jacana, Hydrophasianus), the spur-winged goose (Plectropterus), the torrent duck (Merganetta) and nine species of lapwing (Vanellus) use a sharp spur on the wing as a weapon. The steamer ducks (Tachyeres), geese and swans (Anserinae), the solitaire (Pezophaps), sheathbills (Chionis), some guans (Crax) and stone curlews (Burhinus) use a bony knob on the alular metacarpal to punch and hammer opponents.[93] The jacanas Actophilornis and Irediparra have an expanded, blade-like radius. The extinct Xenicibis was unique in having an elongate forelimb and massive hand which likely functioned in combat or defence as a jointed club or flail. Swans, for instance, may strike with the bony spurs and bite when defending eggs or young.[93]

Chromosomes

Birds have two sexes: either female or male. The sex of birds is determined by the Z and W sex chromosomes, rather than by the X and Y chromosomes present in mammals. Male birds have two Z chromosomes (ZZ), and female birds have a W chromosome and a Z chromosome (WZ).[58]

In nearly all species of birds, an individual's sex is determined at fertilisation. However, one recent study demonstrated temperature-dependent sex determination among the Australian brushturkey, for which higher temperatures during incubation resulted in a higher female-to-male sex ratio.[94] This, however, was later proven to not be the case. These birds do not exhibit temperature-dependent sex determination, but temperature-dependent sex mortality.[95]

Feathers, plumage, and scales

Main articles: Feather and Flight feather
Owl with eyes closed in front of similarly coloured tree trunk partly obscured by green leaves
The plumage of the African scops owl allows it to blend in with its surroundings.

Feathers are a feature characteristic of birds (though also present in some dinosaurs not currently considered to be true birds). They facilitate flight, provide insulation that aids in thermoregulation, and are used in display, camouflage, and signalling.[58] There are several types of feathers, each serving its own set of purposes. Feathers are epidermal growths attached to the skin and arise only in specific tracts of skin called pterylae. The distribution pattern of these feather tracts (pterylosis) is used in taxonomy and systematics. The arrangement and appearance of feathers on the body, called plumage, may vary within species by age, social status,[96] and sex.[97]

Plumage is regularly moulted; the standard plumage of a bird that has moulted after breeding is known as the "non-breeding" plumage, or—in the Humphrey-Parkes terminology—"basic" plumage; breeding plumages or variations of the basic plumage are known under the Humphrey-Parkes system as "alternate" plumages.[98] Moulting is annual in most species, although some may have two moults a year, and large birds of prey may moult only once every few years. Moulting patterns vary across species. In passerines, flight feathers are replaced one at a time with the innermost primary being the first. When the fifth of sixth primary is replaced, the outermost tertiaries begin to drop. After the innermost tertiaries are moulted, the secondaries starting from the innermost begin to drop and this proceeds to the outer feathers (centrifugal moult). The greater primary coverts are moulted in synchrony with the primary that they overlap.[99] A small number of species, such as ducks and geese, lose all of their flight feathers at once, temporarily becoming flightless.[100] As a general rule, the tail feathers are moulted and replaced starting with the innermost pair.[99] Centripetal moults of tail feathers are however seen in the Phasianidae.[101] The centrifugal moult is modified in the tail feathers of woodpeckers and treecreepers, in that it begins with the second innermost pair of feathers and finishes with the central pair of feathers so that the bird maintains a functional climbing tail.[99][102] The general pattern seen in passerines is that the primaries are replaced outward, secondaries inward, and the tail from centre outward.[103] Before nesting, the females of most bird species gain a bare brood patch by losing feathers close to the belly. The skin there is well supplied with blood vessels and helps the bird in incubation.[104]

Red parrot with yellow bill and wing feathers in bill
Red lory preening

Feathers require maintenance and birds preen or groom them daily, spending an average of around 9% of their daily time on this.[105] The bill is used to brush away foreign particles and to apply waxy secretions from the uropygial gland; these secretions protect the feathers' flexibility and act as an antimicrobial agent, inhibiting the growth of feather-degrading bacteria.[106] This may be supplemented with the secretions of formic acid from ants, which birds receive through a behaviour known as anting, to remove feather parasites.[107]

The scales of birds are composed of the same keratin as beaks, claws, and spurs. They are found mainly on the toes and metatarsus, but may be found further up on the ankle in some birds. Most bird scales do not overlap significantly, except in the cases of kingfishers and woodpeckers. The scales of birds are thought to be homologous to those of reptiles and mammals.[108]

Flight

Main article: Bird flight
Black bird with white chest in flight with wings facing down and tail fanned and down pointing
Restless flycatcher in the downstroke of flapping flight

Most birds can fly, which distinguishes them from almost all other vertebrate classes. Flight is the primary means of locomotion for most bird species and is used for breeding, feeding, and predator avoidance and escape. Birds have various adaptations for flight, including a lightweight skeleton, two large flight muscles, the pectoralis (which accounts for 15% of the total mass of the bird) and the supracoracoideus, as well as a modified forelimb (wing) that serves as an aerofoil.[58] Wing shape and size generally determine a bird species' type of flight; many birds combine powered, flapping flight with less energy-intensive soaring flight. About 60 extant bird species are flightless, as were many extinct birds.[109] Flightlessness often arises in birds on isolated islands, probably due to limited resources and the absence of land predators.[110] Though flightless, penguins use similar musculature and movements to "fly" through the water, as do auks, shearwaters and dippers.[111]

Behaviour

Most birds are diurnal, but some birds, such as many species of owls and nightjars, are nocturnal or crepuscular (active during twilight hours), and many coastal waders feed when the tides are appropriate, by day or night.[112]

Diet and feeding

 Illustration of the heads of 16 types of birds with different shapes and sizes of beak
Feeding adaptations in beaks

Birds' diets are varied and often include nectar, fruit, plants, seeds, carrion, and various small animals, including other birds.[58] Because birds have no teeth, their digestive system is adapted to process unmasticated food items that are swallowed whole.[113]

Birds that employ many strategies to obtain food or feed on a variety of food items are called generalists, while others that concentrate time and effort on specific food items or have a single strategy to obtain food are considered specialists.[58] Birds' feeding strategies vary by species. Many birds glean for insects, invertebrates, fruit, or seeds. Some hunt insects by suddenly attacking from a branch. Those species that seek pest insects are considered beneficial 'biological control agents' and their presence encouraged in biological pest control programmes.[114] Nectar feeders such as hummingbirds, sunbirds, lories, and lorikeets amongst others have specially adapted brushy tongues and in many cases bills designed to fit co-adapted flowers.[115] Kiwis and shorebirds with long bills probe for invertebrates; shorebirds' varied bill lengths and feeding methods result in the separation of ecological niches.[58][116] Loons, diving ducks, penguins and auks pursue their prey underwater, using their wings or feet for propulsion,[50] while aerial predators such as sulids, kingfishers and terns plunge dive after their prey. Flamingos, three species of prion, and some ducks are filter feeders.[117][118] Geese and dabbling ducks are primarily grazers.

Some species, including frigatebirds, gulls,[119] and skuas,[120] engage in kleptoparasitism, stealing food items from other birds. Kleptoparasitism is thought to be a supplement to food obtained by hunting, rather than a significant part of any species' diet; a study of great frigatebirds stealing from masked boobies estimated that the frigatebirds stole at most 40% of their food and on average stole only 5%.[121] Other birds are scavengers; some of these, like vultures, are specialised carrion eaters, while others, like gulls, corvids, or other birds of prey, are opportunists.[122]

Water and drinking

Water is needed by many birds although their mode of excretion and lack of sweat glands reduces the physiological demands.[123] Some desert birds can obtain their water needs entirely from moisture in their food. They may also have other adaptations such as allowing their body temperature to rise, saving on moisture loss from evaporative cooling or panting.[124] Seabirds can drink seawater and have salt glands inside the head that eliminate excess salt out of the nostrils.[125]

Most birds scoop water in their beaks and raise their head to let water run down the throat. Some species, especially of arid zones, belonging to the pigeon, finch, mousebird, button-quail and bustard families are capable of sucking up water without the need to tilt back their heads.[126] Some desert birds depend on water sources and sandgrouse are particularly well known for their daily congregations at waterholes. Nesting sandgrouse and many plovers carry water to their young by wetting their belly feathers.[127] Some birds carry water for chicks at the nest in their crop or regurgitate it along with food. The pigeon family, flamingos and penguins have adaptations to produce a nutritive fluid called crop milk that they provide to their chicks.[128]

Feather care

Feathers being critical to the survival of a bird, require maintenance. Apart from physical wear and tear, feathers face the onslaught of fungi, ectoparasitic feather mites and birdlice.[129] The physical condition of feathers are maintained by preening often with the application of secretions from the preen gland. Birds also bathe in water or dust themselves. While some birds dip into shallow water, more aerial species may make aerial dips into water and arboreal species often make use of dew or rain that collect on leaves. Birds of arid regions make use of loose soil to dust-bathe. A behaviour termed as anting in which the bird encourages ants to run through their plumage is also thought to help them reduce the ectoparasite load in feathers. Many species will spread out their wings and expose them to direct sunlight and this too is thought to help in reducing fungal and ectoparasitic activity that may lead to feather damage.[130][131]

Migration

Main article: Bird migration
A flock of Canada geese in V formation.

Many bird species migrate to take advantage of global differences of seasonal temperatures, therefore optimising availability of food sources and breeding habitat. These migrations vary among the different groups. Many landbirds, shorebirds, and waterbirds undertake annual long distance migrations, usually triggered by the length of daylight as well as weather conditions. These birds are characterised by a breeding season spent in the temperate or polar regions and a non-breeding season in the tropical regions or opposite hemisphere. Before migration, birds substantially increase body fats and reserves and reduce the size of some of their organs.[73][132] Migration is highly demanding energetically, particularly as birds need to cross deserts and oceans without refuelling. Landbirds have a flight range of around 2,500 km (1,600 mi) and shorebirds can fly up to 4,000 km (2,500 mi),[133] although the bar-tailed godwit is capable of non-stop flights of up to 10,200 km (6,300 mi).[134] Seabirds also undertake long migrations, the longest annual migration being those of sooty shearwaters, which nest in New Zealand and Chile and spend the northern summer feeding in the North Pacific off Japan, Alaska and California, an annual round trip of 64,000 km (39,800 mi).[135] Other seabirds disperse after breeding, travelling widely but having no set migration route. Albatrosses nesting in the Southern Ocean often undertake circumpolar trips between breeding seasons.[136]

 A map of the Pacific Ocean with several coloured lines representing bird routes running from New Zealand to Korea
The routes of satellite-tagged bar-tailed godwits migrating north from New Zealand. This species has the longest known non-stop migration of any species, up to 10,200 km (6,300 mi).

Some bird species undertake shorter migrations, travelling only as far as is required to avoid bad weather or obtain food. Irruptive species such as the boreal finches are one such group and can commonly be found at a location in one year and absent the next. This type of migration is normally associated with food availability.[137] Species may also travel shorter distances over part of their range, with individuals from higher latitudes travelling into the existing range of conspecifics; others undertake partial migrations, where only a fraction of the population, usually females and subdominant males, migrates.[138] Partial migration can form a large percentage of the migration behaviour of birds in some regions; in Australia, surveys found that 44% of non-passerine birds and 32% of passerines were partially migratory.[139] Altitudinal migration is a form of short distance migration in which birds spend the breeding season at higher altitudes elevations and move to lower ones during suboptimal conditions. It is most often triggered by temperature changes and usually occurs when the normal territories also become inhospitable due to lack of food.[140] Some species may also be nomadic, holding no fixed territory and moving according to weather and food availability. Parrots as a family are overwhelmingly neither migratory nor sedentary but considered to either be dispersive, irruptive, nomadic or undertake small and irregular migrations.[141]

The ability of birds to return to precise locations across vast distances has been known for some time; in an experiment conducted in the 1950s a Manx shearwater released in Boston returned to its colony in Skomer, Wales, within 13 days, a distance of 5,150 km (3,200 mi).[142] Birds navigate during migration using a variety of methods. For diurnal migrants, the sun is used to navigate by day, and a stellar compass is used at night. Birds that use the sun compensate for the changing position of the sun during the day by the use of an internal clock.[58] Orientation with the stellar compass depends on the position of the constellations surrounding Polaris.[143] These are backed up in some species by their ability to sense the Earth's geomagnetism through specialised photoreceptors.[144]

Communication

Large brown patterned ground bird with outstretched wings each with a large spot in the centre
The startling display of the sunbittern mimics a large predator.

Birds communicate using primarily visual and auditory signals. Signals can be interspecific (between species) and intraspecific (within species).

Birds sometimes use plumage to assess and assert social dominance,[145] to display breeding condition in sexually selected species, or to make threatening displays, as in the sunbittern's mimicry of a large predator to ward off hawks and protect young chicks.[146] Variation in plumage also allows for the identification of birds, particularly between species. Visual communication among birds may also involve ritualised displays, which have developed from non-signalling actions such as preening, the adjustments of feather position, pecking, or other behaviour. These displays may signal aggression or submission or may contribute to the formation of pair-bonds.[58] The most elaborate displays occur during courtship, where "dances" are often formed from complex combinations of many possible component movements;[147] males' breeding success may depend on the quality of such displays.[148]

Bird song
Song of the house wren, a common North American songbird

Problems playing this file? See media help.

Bird calls and songs, which are produced in the syrinx, are the major means by which birds communicate with sound. This communication can be very complex; some species can operate the two sides of the syrinx independently, allowing the simultaneous production of two different songs.[75] Calls are used for a variety of purposes, including mate attraction,[58] evaluation of potential mates,[149] bond formation, the claiming and maintenance of territories,[58] the identification of other individuals (such as when parents look for chicks in colonies or when mates reunite at the start of breeding season),[150] and the warning of other birds of potential predators, sometimes with specific information about the nature of the threat.[151] Some birds also use mechanical sounds for auditory communication. The Coenocorypha snipes of New Zealand drive air through their feathers,[152] woodpeckers drum territorially,[72] and palm cockatoos use tools to drum.[153]

 massive flock of tiny birds seen from distance so that birds appear as specks
Red-billed queleas, the most numerous species of bird,[154] form enormous flocks—sometimes tens of thousands strong.

Flocking and other associations

While some birds are essentially territorial or live in small family groups, other birds may form large flocks. The principal benefits of flocking are safety in numbers and increased foraging efficiency.[58] Defence against predators is particularly important in closed habitats like forests, where ambush predation is common and multiple eyes can provide a valuable early warning system. This has led to the development of many mixed-species feeding flocks, which are usually composed of small numbers of many species; these flocks provide safety in numbers but increase potential competition for resources.[155] Costs of flocking include bullying of socially subordinate birds by more dominant birds and the reduction of feeding efficiency in certain cases.[156]

Birds sometimes also form associations with non-avian species. Plunge-diving seabirds associate with dolphins and tuna, which push shoaling fish towards the surface.[157] Hornbills have a mutualistic relationship with dwarf mongooses, in which they forage together and warn each other of nearby birds of prey and other predators.[158]

Resting and roosting

Pink flamingo with grey legs and long neck pressed against body and head tucked under wings
Many birds, like this American flamingo, tuck their head into their back when sleeping

The high metabolic rates of birds during the active part of the day is supplemented by rest at other times. Sleeping birds often use a type of sleep known as vigilant sleep, where periods of rest are interspersed with quick eye-opening "peeks", allowing them to be sensitive to disturbances and enable rapid escape from threats.[159] Swifts are believed to be able to sleep in flight and radar observations suggest that they orient themselves to face the wind in their roosting flight.[160] It has been suggested that there may be certain kinds of sleep which are possible even when in flight.[161] Some birds have also demonstrated the capacity to fall into slow-wave sleep one hemisphere of the brain at a time. The birds tend to exercise this ability depending upon its position relative to the outside of the flock. This may allow the eye opposite the sleeping hemisphere to remain vigilant for predators by viewing the outer margins of the flock. This adaptation is also known from marine mammals.[162] Communal roosting is common because it lowers the loss of body heat and decreases the risks associated with predators.[163] Roosting sites are often chosen with regard to thermoregulation and safety.[164]

Many sleeping birds bend their heads over their backs and tuck their bills in their back feathers, although others place their beaks among their breast feathers. Many birds rest on one leg, while some may pull up their legs into their feathers, especially in cold weather. Perching birds have a tendon locking mechanism that helps them hold on to the perch when they are asleep. Many ground birds, such as quails and pheasants, roost in trees. A few parrots of the genus Loriculus roost hanging upside down.[165] Some hummingbirds go into a nightly state of torpor accompanied with a reduction of their metabolic rates.[166] This physiological adaptation shows in nearly a hundred other species, including owlet-nightjars, nightjars, and woodswallows. One species, the common poorwill, even enters a state of hibernation.[167] Birds do not have sweat glands, but they may cool themselves by moving to shade, standing in water, panting, increasing their surface area, fluttering their throat or by using special behaviours like urohidrosis to cool themselves.

Breeding

See also: Animal sexual behaviour § Birds, Seabird breeding behaviour, and Sexual selection in birds

Social systems

 Bird faces up with green face, black breast and pink lower body. Elaborate long feathers on the wings and tail.
Like others of its family the male Raggiana bird-of-paradise has elaborate breeding plumage used to impress females.[168]

Ninety-five per cent of bird species are socially monogamous. These species pair for at least the length of the breeding season or—in some cases—for several years or until the death of one mate.[169] Monogamy allows for both paternal care and biparental care, which is especially important for species in which females require males' assistance for successful brood-rearing.[170] Among many socially monogamous species, extra-pair copulation (infidelity) is common.[171] Such behaviour typically occurs between dominant males and females paired with subordinate males, but may also be the result of forced copulation in ducks and other anatids.[172] Female birds have sperm storage mechanisms that allow sperm from males to remain viable long after copulation, a hundred days in some species.[173] Sperm from multiple males may compete through this mechanism. For females, possible benefits of extra-pair copulation include getting better genes for her offspring and insuring against the possibility of infertility in her mate.[174] Males of species that engage in extra-pair copulations will closely guard their mates to ensure the parentage of the offspring that they raise.[175]

Other mating systems, including polygyny, polyandry, polygamy, polygynandry, and promiscuity, also occur.[58] Polygamous breeding systems arise when females are able to raise broods without the help of males.[58] Some species may use more than one system depending on the circumstances.

Breeding usually involves some form of courtship display, typically performed by the male.[176] Most displays are rather simple and involve some type of song. Some displays, however, are quite elaborate. Depending on the species, these may include wing or tail drumming, dancing, aerial flights, or communal lekking. Females are generally the ones that drive partner selection,[177] although in the polyandrous phalaropes, this is reversed: plainer males choose brightly coloured females.[178] Courtship feeding, billing and allopreening are commonly performed between partners, generally after the birds have paired and mated.[72]

Homosexual behaviour has been observed in males or females in numerous species of birds, including copulation, pair-bonding, and joint parenting of chicks.[179]

Territories, nesting and incubation

See also: Bird nest

Many birds actively defend a territory from others of the same species during the breeding season; maintenance of territories protects the food source for their chicks. Species that are unable to defend feeding territories, such as seabirds and swifts, often breed in colonies instead; this is thought to offer protection from predators. Colonial breeders defend small nesting sites, and competition between and within species for nesting sites can be intense.[180]

All birds lay amniotic eggs with hard shells made mostly of calcium carbonate.[58] Hole and burrow nesting species tend to lay white or pale eggs, while open nesters lay camouflaged eggs. There are many exceptions to this pattern, however; the ground-nesting nightjars have pale eggs, and camouflage is instead provided by their plumage. Species that are victims of brood parasites have varying egg colours to improve the chances of spotting a parasite's egg, which forces female parasites to match their eggs to those of their hosts.[181]

Yellow weaver (bird) with black head hangs an upside-down nest woven out of grass fronds.
Male golden-backed weavers construct elaborate suspended nests out of grass.

Bird eggs are usually laid in a nest. Most species create somewhat elaborate nests, which can be cups, domes, plates, beds scrapes, mounds, or burrows.[182] Some bird nests, however, are extremely primitive; albatross nests are no more than a scrape on the ground. Most birds build nests in sheltered, hidden areas to avoid predation, but large or colonial birds—which are more capable of defence—may build more open nests. During nest construction, some species seek out plant matter from plants with parasite-reducing toxins to improve chick survival,[183] and feathers are often used for nest insulation.[182] Some bird species have no nests; the cliff-nesting common guillemot lays its eggs on bare rock, and male emperor penguins keep eggs between their body and feet. The absence of nests is especially prevalent in ground-nesting species where the newly hatched young are precocial.

 Nest made of straw with five white eggs and one grey speckled egg
Nest of an eastern phoebe that has been parasitised by a brown-headed cowbird.

Incubation, which optimises temperature for chick development, usually begins after the last egg has been laid.[58] In monogamous species incubation duties are often shared, whereas in polygamous species one parent is wholly responsible for incubation. Warmth from parents passes to the eggs through brood patches, areas of bare skin on the abdomen or breast of the incubating birds. Incubation can be an energetically demanding process; adult albatrosses, for instance, lose as much as 83 grams (2.9 oz) of body weight per day of incubation.[184] The warmth for the incubation of the eggs of megapodes comes from the sun, decaying vegetation or volcanic sources.[185] Incubation periods range from 10 days (in woodpeckers, cuckoos and passerine birds) to over 80 days (in albatrosses and kiwis).[58]

The diversity of characteristics of birds is great, sometimes even in closely related species. Several avian characteristics are compared in the table below.[186][187]

Species Adult weight

(grams)

Incubation

(days)

Clutches

(per year)

Clutch size
Ruby-throated hummingbird (Archilochus colubris) 3 13 2.0 2
House sparrow (Passer domesticus) 25 11 4.5 5
Greater roadrunner (Geococcyx californianus) 376 20 1.5 4
Turkey vulture (Cathartes aura) 2,200 39 1.0 2
Laysan albatross (Diomedea immutabilis) 3,150 64 1.0 1
Magellanic penguin (Spheniscus magellanicus) 4,000 40 1.0 1
Golden eagle (Aquila chrysaetos) 4,800 40 1.0 2
Wild turkey (Meleagris gallopavo) 6,050 28 1.0 11
Columns are sortable

Parental care and fledging

At the time of their hatching, chicks range in development from helpless to independent, depending on their species. Helpless chicks are termed altricial, and tend to be born small, blind, immobile and naked; chicks that are mobile and feathered upon hatching are termed precocial. Altricial chicks need help thermoregulating and must be brooded for longer than precocial chicks. Chicks at neither of these extremes can be semi-precocial or semi-altricial.

Hummingbird perched on edge of tiny nest places food into mouth of one of two chicks
A female Calliope hummingbird feeding fully grown chicks.

The length and nature of parental care varies widely amongst different orders and species. At one extreme, parental care in megapodes ends at hatching; the newly hatched chick digs itself out of the nest mound without parental assistance and can fend for itself immediately.[188] At the other extreme, many seabirds have extended periods of parental care, the longest being that of the great frigatebird, whose chicks take up to six months to fledge and are fed by the parents for up to an additional 14 months.[189] The chick guard stage describes the period of breeding during which one of the adult birds is permanently present at the nest after chicks have hatched. The main purpose of the guard stage is to aid offspring to thermoregulate and protect them from predation.[190]

In some species, both parents care for nestlings and fledglings; in others, such care is the responsibility of only one sex. In some species, other members of the same species—usually close relatives of the breeding pair, such as offspring from previous broods—will help with the raising of the young.[191] Such alloparenting is particularly common among the Corvida, which includes such birds as the true crows, Australian magpie and fairy-wrens,[192] but has been observed in species as different as the rifleman and red kite. Among most groups of animals, male parental care is rare. In birds, however, it is quite common—more so than in any other vertebrate class.[58] Though territory and nest site defence, incubation, and chick feeding are often shared tasks, there is sometimes a division of labour in which one mate undertakes all or most of a particular duty.[193]

The point at which chicks fledge varies dramatically. The chicks of the Synthliboramphus murrelets, like the ancient murrelet, leave the nest the night after they hatch, following their parents out to sea, where they are raised away from terrestrial predators.[194] Some other species, such as ducks, move their chicks away from the nest at an early age. In most species, chicks leave the nest just before, or soon after, they are able to fly. The amount of parental care after fledging varies; albatross chicks leave the nest on their own and receive no further help, while other species continue some supplementary feeding after fledging.[195] Chicks may also follow their parents during their first migration.[196]

Brood parasites

Main article: Brood parasite

Brood parasitism, in which an egg-layer leaves her eggs with another individual's brood, is more common among birds than any other type of organism.[197] After a parasitic bird lays her eggs in another bird's nest, they are often accepted and raised by the host at the expense of the host's own brood. Brood parasites may be either obligate brood parasites, which must lay their eggs in the nests of other species because they are incapable of raising their own young, or non-obligate brood parasites, which sometimes lay eggs in the nests of conspecifics to increase their reproductive output even though they could have raised their own young.[198] One hundred bird species, including honeyguides, icterids, and ducks, are obligate parasites, though the most famous are the cuckoos.[197] Some brood parasites are adapted to hatch before their host's young, which allows them to destroy the host's eggs by pushing them out of the nest or to kill the host's chicks; this ensures that all food brought to the nest will be fed to the parasitic chicks.[199]

Sexual selection

The peacock tail in flight, the classic example of a Fisherian runaway

Birds have evolved a variety of mating behaviours, with the peacock tail being perhaps the most famous example of sexual selection and the Fisherian runaway. Commonly occurring sexual dimorphisms such as size and colour differences are energetically costly attributes that signal competitive breeding situations.[200] Many types of avian sexual selection have been identified; intersexual selection, also known as female choice; and intrasexual competition, where individuals of the more abundant sex compete with each other for the privilege to mate. Sexually selected traits often evolve to become more pronounced in competitive breeding situations until the trait begins to limit the individual’s fitness. Conflicts between an individual fitness and signalling adaptations ensure that sexually selected ornaments such as plumage coloration and courtship behaviour are "honest" traits. Signals must be costly to ensure that only good-quality individuals can present these exaggerated sexual ornaments and behaviours.[201]

Inbreeding depression

Main article: Inbreeding depression

Inbreeding causes early death (inbreeding depression) in the zebra finch Taeniopygia guttata.[202] Embryo survival (that is, hatching success of fertile eggs) was significantly lower for sib-sib mating pairs than for unrelated pairs.

Darwin’s finch Geospiza scandens experiences inbreeding depression (reduced survival of offspring) and the magnitude of this effect is influenced by environmental conditions such as low food availability.[203]

Inbreeding avoidance

Main article: Inbreeding avoidance

Incestuous matings by the purple-crowned fairy wren Malurus coronatus result in severe fitness costs due to inbreeding depression (greater than 30% reduction in hatchability of eggs).[204] Females paired with related males may undertake extra pair matings (see Promiscuity#Other animals for 90% frequency in avian species) that can reduce the negative effects of inbreeding. However, there are ecological and demographic constraints on extra pair matings. Nevertheless, 43% of broods produced by incestuously paired females contained extra pair young.[204]

Inbreeding depression occurs in the great tit (Parus major) when the offspring produced as a result of a mating between close relatives show reduced fitness. In natural populations of Parus major, inbreeding is avoided by dispersal of individuals from their birthplace, which reduces the chance of mating with a close relative.[205]

Southern pied babblers Turdoides bicolor appear to avoid inbreeding in two ways. The first is through dispersal, and the second is by avoiding familiar group members as mates.[206] Although both males and females disperse locally, they move outside the range where genetically related individuals are likely to be encountered. Within their group, individuals only acquire breeding positions when the opposite-sex breeder is unrelated.

Cooperative breeding in birds typically occurs when offspring, usually males, delay dispersal from their natal group in order to remain with the family to help rear younger kin.[207] Female offspring rarely stay at home, dispersing over distances that allow them to breed independently, or to join unrelated groups. In general, inbreeding is avoided because it leads to a reduction in progeny fitness (inbreeding depression) due largely to the homozygous expression of deleterious recessive alleles.[208] Cross-fertilisation between unrelated individuals ordinarily leads to the masking of deleterious recessive alleles in progeny.[209][210]

Ecology

Gran Canaria blue chaffinch, an example of a bird highly specialised in its habitat, in this case in the Canarian pine forests.

Birds occupy a wide range of ecological positions.[154] While some birds are generalists, others are highly specialised in their habitat or food requirements. Even within a single habitat, such as a forest, the niches occupied by different species of birds vary, with some species feeding in the forest canopy, others beneath the canopy, and still others on the forest floor. Forest birds may be insectivores, frugivores, and nectarivores. Aquatic birds generally feed by fishing, plant eating, and piracy or kleptoparasitism. Birds of prey specialise in hunting mammals or other birds, while vultures are specialised scavengers. Avivores are animals that are specialised at preying on birds.

Some nectar-feeding birds are important pollinators, and many frugivores play a key role in seed dispersal.[211] Plants and pollinating birds often coevolve,[212] and in some cases a flower's primary pollinator is the only species capable of reaching its nectar.[213]

Birds are often important to island ecology. Birds have frequently reached islands that mammals have not; on those islands, birds may fulfil ecological roles typically played by larger animals. For example, in New Zealand the moas were important browsers, as are the kereru and kokako today.[211] Today the plants of New Zealand retain the defensive adaptations evolved to protect them from the extinct moa.[214] Nesting seabirds may also affect the ecology of islands and surrounding seas, principally through the concentration of large quantities of guano, which may enrich the local soil[215] and the surrounding seas.[216]

A wide variety of avian ecology field methods, including counts, nest monitoring, and capturing and marking, are used for researching avian ecology.

Relationship with humans

Main article: Birds in culture

Since birds are highly visible and common animals, humans have had a relationship with them since the dawn of man.[217] Sometimes, these relationships are mutualistic, like the cooperative honey-gathering among honeyguides and African peoples such as the Borana.[218] Other times, they may be commensal, as when species such as the house sparrow[219] have benefited from human activities. Several bird species have become commercially significant agricultural pests,[220] and some pose an aviation hazard.[221] Human activities can also be detrimental, and have threatened numerous bird species with extinction (hunting, avian lead poisoning, pesticides, roadkill, and predation by pet cats and dogs are common sources of death for birds).

Birds can act as vectors for spreading diseases such as psittacosis, salmonellosis, campylobacteriosis, mycobacteriosis (avian tuberculosis), avian influenza (bird flu), giardiasis, and cryptosporidiosis over long distances. Some of these are zoonotic diseases that can also be transmitted to humans.[222]

Economic importance

See also: Pet § Birds

Domesticated birds raised for meat and eggs, called poultry, are the largest source of animal protein eaten by humans; in 2003, 76 million tons of poultry and 61 million tons of eggs were produced worldwide.[223] Chickens account for much of human poultry consumption, though domesticated turkeys, ducks, and geese are also relatively common. Many species of birds are also hunted for meat. Bird hunting is primarily a recreational activity except in extremely undeveloped areas. The most important birds hunted in North and South America are waterfowl; other widely hunted birds include pheasants, wild turkeys, quail, doves, partridge, grouse, snipe, and woodcock.[224] Muttonbirding is also popular in Australia and New Zealand.[225] Though some hunting, such as that of muttonbirds, may be sustainable, hunting has led to the extinction or endangerment of dozens of species.[226]

 Illustration of fisherman on raft with pole for punting and numerous black birds on raft
The use of cormorants by Asian fishermen is in steep decline but survives in some areas as a tourist attraction.

Other commercially valuable products from birds include feathers (especially the down of geese and ducks), which are used as insulation in clothing and bedding, and seabird faeces (guano), which is a valuable source of phosphorus and nitrogen. The War of the Pacific, sometimes called the Guano War, was fought in part over the control of guano deposits.[227]

Birds have been domesticated by humans both as pets and for practical purposes. Colourful birds, such as parrots and mynas, are bred in captivity or kept as pets, a practice that has led to the illegal trafficking of some endangered species.[228] Falcons and cormorants have long been used for hunting and fishing, respectively. Messenger pigeons, used since at least 1 AD, remained important as recently as World War II. Today, such activities are more common either as hobbies, for entertainment and tourism,[229] or for sports such as pigeon racing.

Amateur bird enthusiasts (called birdwatchers, twitchers or, more commonly, birders) number in the millions.[230] Many homeowners erect bird feeders near their homes to attract various species. Bird feeding has grown into a multimillion-dollar industry; for example, an estimated 75% of households in Britain provide food for birds at some point during the winter.[231]

In religion and mythology

Woodcut of three long-legged and long-necked birds
"The 3 of Birds" by the Master of the Playing Cards, 15th-century Germany
A Swiss singing bird box, c. 1810. An example of the interests of human beings in birds, in this case emulating nature with an automaton version.

Birds play prominent and diverse roles in religion and mythology. In religion, birds may serve as either messengers or priests and leaders for a deity, such as in the Cult of Makemake, in which the Tangata manu of Easter Island served as chiefs[232] or as attendants, as in the case of Hugin and Munin, the two common ravens who whispered news into the ears of the Norse god Odin.[233] In several civilisations of ancient Italy, particularly Etruscan and Roman religion, priests were involved in augury, or interpreting the words of birds while the "auspex" (from which the word "auspicious" is derived) watched their activities to foretell events.[234] They may also serve as religious symbols, as when Jonah (Hebrew: יוֹנָה, dove) embodied the fright, passivity, mourning, and beauty traditionally associated with doves.[235] Birds have themselves been deified, as in the case of the common peacock, which is perceived as Mother Earth by the Dravidians of India.[236] In religious images preserved from the Inca and Tiwanaku empires, birds are depicted in the process of transgressing boundaries between earthly and underground spiritual realms.[237] Indigenous peoples of the central Andes maintain legends of birds passing to and from metaphysical worlds.[237]

In culture and folklore

painted tiles with design of birds from Qajar dynasty

Birds have featured in culture and art since prehistoric times, when they were represented in early cave paintings.[238] Some birds have been perceived as monsters, including the mythological Roc and the Māori's legendary Pouākai, a giant bird capable of snatching humans.[239] Birds were later used as symbols of power, as in the magnificent Peacock Throne of the Mughal and Persian emperors.[240] With the advent of scientific interest in birds, many paintings of birds were commissioned for books. Among the most famous of these bird artists was John James Audubon, whose paintings of North American birds were a great commercial success in Europe and who later lent his name to the National Audubon Society.[241] Birds are also important figures in poetry; for example, Homer incorporated nightingales into his Odyssey, and Catullus used a sparrow as an erotic symbol in his Catullus 2.[242] The relationship between an albatross and a sailor is the central theme of Samuel Taylor Coleridge's The Rime of the Ancient Mariner, which led to the use of the term as a metaphor for a 'burden'.[243] Other English metaphors derive from birds; vulture funds and vulture investors, for instance, take their name from the scavenging vulture.[244]

Perceptions of bird species vary across cultures. Owls are associated with bad luck, witchcraft, and death in parts of Africa,[245] but are regarded as wise across much of Europe.[246] Hoopoes were considered sacred in Ancient Egypt and symbols of virtue in Persia, but were thought of as thieves across much of Europe and harbingers of war in Scandinavia.[247]

In music

In music, birdsong has influenced composers and musicians in several ways: they can be inspired by birdsong; they can intentionally imitate bird song in a composition, as Vivaldi and Beethoven did, along with many later composers; they can incorporate recordings of birds into their works, as Ottorino Respighi first did; or like Beatrice Harrison and David Rothenberg, they can duet with birds.[248][249][250]

Conservation

Large black bird with featherless head and hooked bill
The California condor once numbered only 22 birds, but conservation measures have raised that to over 300 today.
Main article: Bird conservation

Though human activities have allowed the expansion of a few species, such as the barn swallow and European starling, they have caused population decreases or extinction in many other species. Over a hundred bird species have gone extinct in historical times,[251] although the most dramatic human-caused avian extinctions, eradicating an estimated 750–1800 species, occurred during the human colonisation of Melanesian, Polynesian, and Micronesian islands.[252] Many bird populations are declining worldwide, with 1,227 species listed as threatened by BirdLife International and the IUCN in 2009.[253][254]

The most commonly cited human threat to birds is habitat loss.[255] Other threats include overhunting, accidental mortality due to collisions with buildings or vehicles, long-line fishing bycatch,[256] pollution (including oil spills and pesticide use),[257] competition and predation from nonnative invasive species,[258] and climate change.

Governments and conservation groups work to protect birds, either by passing laws that preserve and restore bird habitat or by establishing captive populations for reintroductions. Such projects have produced some successes; one study estimated that conservation efforts saved 16 species of bird that would otherwise have gone extinct between 1994 and 2004, including the California condor and Norfolk parakeet.[259]

See also

Notes

  1. 1 2 3 4 Lee, Michael SY; Cau, Andrea; Darren, Naish; Gareth J., Dyke (2013). "Morphological Clocks in Paleontology, and a Mid-Cretaceous Origin of Crown Aves". Systematic Biology. Oxford Journals. 63: 442–449. doi:10.1093/sysbio/syt110. PMID 24449041.
  2. Brands, Sheila (14 August 2008). "Systema Naturae 2000 / Classification, Class Aves". Project: The Taxonomicon. Retrieved 11 June 2012.
  3. http://www.ucmp.berkeley.edu/diapsids/avians.html
  4. Brown, J.W. & Van Tuinen, M. (2011). "Evolving Perceptions on the Antiquity of the Modern Avian Tree, in Living Dinosaurs". The Evolutionary History of Modern Birds. John Wiley & Sons LtD: 306–324. doi:10.1002/9781119990475.ch12. ISBN 9781119990475.
  5. "Influence of Earth's history on the dawn of modern birds". www.sciencedaily.com. American Museum of Natural History. December 11, 2015. Retrieved December 11, 2015.
  6. Alonso, P. D.; Milner, A. C.; Ketcham, R. A.; Cookson, M. J.; Rowe, T. B. (2004). "The avian nature of the brain and inner ear of Archaeopteryx". Nature. 430 (7000): 666–669. Bibcode:2004Natur.430..666A. doi:10.1038/nature02706. PMID 15295597. PDF fulltext Supplementary info
  7. del Hoyo, Josep; Andy Elliott; Jordi Sargatal (1992). Handbook of Birds of the World, Volume 1: Ostrich to Ducks. Barcelona: Lynx Edicions. ISBN 84-87334-10-5.
  8. (Latin) Linnaeus, Carolus (1758). Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Tomus I. Editio decima, reformata. Holmiae. (Laurentii Salvii). p. 824.
  9. 1 2 3 Livezey, Bradley C.; Zusi, RL (January 2007). "Higher-order phylogeny of modern birds (Theropoda, Aves: Neornithes) based on comparative anatomy. II. Analysis and discussion". Zoological Journal of the Linnean Society. 149 (1): 1–95. doi:10.1111/j.1096-3642.2006.00293.x. PMC 2517308Freely accessible. PMID 18784798.
  10. Padian, Kevin; L.M. Chiappe; Chiappe LM (1997). "Bird Origins". In Philip J. Currie and Kevin Padian (eds.). Encyclopedia of Dinosaurs. San Diego: Academic Press. pp. 41–96. ISBN 0-12-226810-5.
  11. Gauthier, Jacques (1986). "Saurischian Monophyly and the origin of birds". In Kevin Padian. The Origin of Birds and the Evolution of Flight. Memoirs of the California Academy of Science 8. San Francisco, CA: Published by California Academy of Sciences. pp. 1–55. ISBN 0-940228-14-9.
  12. 1 2 Gauthier, J., and de Queiroz, K. (2001). "Feathered dinosaurs, flying dinosaurs, crown dinosaurs, and the name Aves." Pp. 7–41 in New perspectives on the origin and early evolution of birds: proceedings of the International Symposium in Honor of John H. Ostrom (J. A. Gauthier and L. F. Gall, eds.). Peabody Museum of Natural History, Yale University, New Haven, Connecticut, U.S.A.
  13. 1 2 Pascal Godefroit, Andrea Cau, Hu Dong-Yu, François Escuillié, Wu Wenhao and Gareth Dyke (2013). "A Jurassic avialan dinosaur from China resolves the early phylogenetic history of birds". Nature. in press (7454): 359–62. doi:10.1038/nature12168. PMID 23719374.
  14. Weishampel, David B.; Dodson, Peter; Osmólska, Halszka (eds.) (2004). The Dinosauria, Second Edition. University of California Press., 861 pp.
  15. Senter, P. (2007). "A new look at the phylogeny of Coelurosauria (Dinosauria: Theropoda)." Journal of Systematic Palaeontology, (doi:10.1017/S1477201907002143).
  16. Gauthier, J. (1986). "Saurischian monophyly and the origin of birds." In: K. Padian, ed. The origin of birds and the evolution of flight. San Francisco: California, Acad.Sci. pp.1–55. (Mem.Calif.Acad.Sci.8.)
  17. 1 2 Cau, Andrea; Brougham, Tom; Naish, Darren (2015). "The phylogenetic affinities of the bizarre Late Cretaceous Romanian theropod Balaur bondoc(Dinosauria, Maniraptora): Dromaeosaurid or flightless bird?". PeerJ. 3: e1032. doi:10.7717/peerj.1032. PMC 4476167Freely accessible. PMID 26157616.
  18. Prum, Richard O. Prum (2008). "Who's Your Daddy". Science. 322 (5909): 1799–1800. doi:10.1126/science.1168808. PMID 19095929.
  19. Paul, Gregory S. (2002). "Looking for the True Bird Ancestor". Dinosaurs of the Air: The Evolution and Loss of Flight in Dinosaurs and Birds. Baltimore: Johns Hopkins University Press. pp. 171–224. ISBN 0-8018-6763-0.
  20. Norell, Mark; Mick Ellison (2005). Unearthing the Dragon: The Great Feathered Dinosaur Discovery. New York: Pi Press. ISBN 0-13-186266-9.
  21. Borenstein, Seth (31 July 2014). "Study traces dinosaur evolution into early birds". Associated Press. Retrieved 3 August 2014.
  22. Lee, Michael S. Y.; Cau, Andrea; Naish, Darren; Dyke, Gareth J. (1 August 2014). "Sustained miniaturization and anatomical innovation in the dinosaurian ancestors of birds". Science. 345 (6196): 562–566. doi:10.1126/science.1252243. Retrieved 2 August 2014.
  23. Xing Xu, Hailu You, Kai Du and Fenglu Han (28 July 2011). "An Archaeopteryx-like theropod from China and the origin of Avialae". Nature. 475 (7357): 465–470. doi:10.1038/nature10288. PMID 21796204.
  24. Turner, Alan H.; Pol, D; Clarke, JA; Erickson, GM; Norell, MA (2007). "A basal dromaeosaurid and size evolution preceding avian flight" (PDF). Science. 317 (5843): 1378–1381. doi:10.1126/science.1144066. PMID 17823350.
  25. Xu, X; Zhou, Z; Wang, X; Kuang, X; Zhang, F; Du, X (2003). "Four-winged dinosaurs from China". Nature. 421 (6921): 335–340. doi:10.1038/nature01342. PMID 12540892.
  26. Luiggi, Christina (July 2011). "On the Origin of Birds". The Scientist. Retrieved 11 June 2012.
  27. Mayr, G.; Pohl, B.; Hartman, S.; Peters, D.S. (2007). "The tenth skeletal specimen of Archaeopteryx". Zoological Journal of the Linnean Society. 149: 97–116. doi:10.1111/j.1096-3642.2006.00245.x.
  28. 1 2 Zheng, X.; Zhou, Z.; Wang, X.; Zhang, F.; Zhang, X.; Wang, Y.; Wei, G.; Wang, S.; Xu, X. (2013). "Hind Wings in Basal Birds and the Evolution of Leg Feathers". Science. 339 (6125): 1309–1312. doi:10.1126/science.1228753. PMID 23493711.
  29. 1 2 3 4 Chiappe, Luis M. (2007). Glorified Dinosaurs: The Origin and Early Evolution of Birds. Sydney: University of New South Wales Press. ISBN 978-0-86840-413-4.
  30. Agency France-Presse (April 2011). "Birds survived dino extinction with keen senses". Cosmos Magazine. Retrieved 11 June 2012.
  31. Wang, M. Zheng, X. O’Connor, J.K. Lloyd, G.T. Wang, X. Wang, Y. Zhang, X. & Zhou, Z. (2015) The oldest record of ornithuromorpha from the early cretaceous of China. Nature Communications, 6:6987.Wang, M.; Zheng, X.; o’Connor, J. K.; Lloyd, G. T.; Wang, X.; Wang, Y.; Zhang, X.; Zhou, Z. (2015). "The oldest record of ornithuromorpha from the early cretaceous of China". Nature Communications. 6: 6987. doi:10.1038/ncomms7987. PMID 25942493.
  32. Clarke, Julia A. (2004). "Morphology, Phylogenetic Taxonomy, and Systematics of Ichthyornis and Apatornis (Avialae: Ornithurae)" (PDF). Bulletin of the American Museum of Natural History. 286: 1–179. doi:10.1206/0003-0090(2004)286<0001:MPTASO>2.0.CO;2.
  33. Louchart, A.; Viriot, L. (2011). "From snout to beak: the loss of teeth in birds". Trends In Ecology & Evolution. 26 (12): 663–673. doi:10.1016/j.tree.2011.09.004.
  34. Clarke, J. A.; Zhou, Z.; Zhang, F. (2006). "Insight into the evolution of avian flight from a new clade of Early Cretaceous ornithurines from China and the morphology of Yixianornis grabaui". Journal of Anatomy. 208 (3): 287–308. doi:10.1111/j.1469-7580.2006.00534.x. PMC 2100246Freely accessible. PMID 16533313.
  35. Ritchison, Gary. "Bird biogeography". Avian Biology. Eastern Kentucky University. Retrieved 10 April 2008.
  36. Clements, James F. (2007). The Clements Checklist of Birds of the World (6th ed.). Ithaca: Cornell University Press. ISBN 978-0-8014-4501-9.
  37. Gill, Frank (2006). Birds of the World: Recommended English Names. Princeton: Princeton University Press. ISBN 978-0-691-12827-6.
  38. Clarke, Julia A.; Tambussi, CP; Noriega, JI; Erickson, GM; Ketcham, RA (2005). "Definitive fossil evidence for the extant avian radiation in the Cretaceous" (PDF). Nature. 433 (7023): 305–308. doi:10.1038/nature03150. PMID 15662422. Nature.com, Supporting information
  39. Clarke, J.A. (2004). "Morphology, phylogenetic taxonomy, and systematics of Ichthyornis and Apatornis (Avialae: Ornithurae)". Bulletin of the American Museum of Natural History. 286: 1–179. doi:10.1206/0003-0090(2004)286<0001:mptaso>2.0.co;2.
  40. 1 2 Ericson, Per G.P.; Anderson, CL; Britton, T; Elzanowski, A; Johansson, US; Källersjö, M; Ohlson, JI; Parsons, TJ; Zuccon, D; et al. (2006). "Diversification of Neoaves: integration of molecular sequence data and fossils" (PDF). Biology Letters. 2 (4): 543–547. doi:10.1098/rsbl.2006.0523. PMC 1834003Freely accessible. PMID 17148284.
  41. Brown, Joseph W.; Payne, RB; Mindell, DP (June 2007). "Nuclear DNA does not reconcile 'rocks' and 'clocks' in Neoaves: a comment on Ericson et al.". Biology Letters. 3 (3): 257–259. doi:10.1098/rsbl.2006.0611. PMC 2464679Freely accessible. PMID 17389215.
  42. Ornithologists Publish Most Comprehensive Avian Tree of Life
  43. 1 2 Jarvis, E.D.; et al. (2014). "Whole-genome analyses resolve early branches in the tree of life of modern birds". Science. 346 (6215): 1320–1331. doi:10.1126/science.1253451. PMC 4405904Freely accessible. PMID 25504713.
  44. Yuri, T.; et al. (2013). "Parsimony and Model-Based Analyses of Indels in Avian Nuclear Genes Reveal Congruent and Incongruent Phylogenetic Signals". Biology. 2 (1): 419–444. doi:10.3390/biology2010419.
  45. Sibley, Charles; Jon Edward Ahlquist (1990). Phylogeny and classification of birds. New Haven: Yale University Press. ISBN 0-300-04085-7.
  46. Mayr, Ernst; Short, Lester L. (1970). Species Taxa of North American Birds: A Contribution to Comparative Systematics. Publications of the Nuttall Ornithological Club, no. 9. Cambridge, Mass.: Nuttall Ornithological Club. OCLC 517185.
  47. Newton, Ian (2003). The Speciation and Biogeography of Birds. Amsterdam: Academic Press. p. 463. ISBN 0-12-517375-X.
  48. Brooke, Michael (2004). Albatrosses And Petrels Across The World. Oxford: Oxford University Press. ISBN 0-19-850125-0.
  49. Weir, Jason T.; Schluter, D (2007). "The Latitudinal Gradient in Recent Speciation and Extinction Rates of Birds and Mammals". Science. 315 (5818): 1574–76. doi:10.1126/science.1135590. PMID 17363673.
  50. 1 2 Schreiber, Elizabeth Anne; Joanna Burger (2001). Biology of Marine Birds. Boca Raton: CRC Press. ISBN 0-8493-9882-7.
  51. Sato, Katsufumi; Naito, Y; Kato, A; Niizuma, Y; Watanuki, Y; Charrassin, JB; Bost, CA; Handrich, Y; Le Maho, Y (1 May 2002). "Buoyancy and maximal diving depth in penguins: do they control inhaling air volume?". Journal of Experimental Biology. 205 (9): 1189–1197. PMID 11948196.
  52. Hill, David; Peter Robertson (1988). The Pheasant: Ecology, Management, and Conservation. Oxford: BSP Professional. ISBN 0-632-02011-3.
  53. Spreyer, Mark F.; Enrique H. Bucher (1998). "Monk Parakeet (Myiopsitta monachus)". The Birds of North America. Cornell Lab of Ornithology. doi:10.2173/bna.322. Retrieved 2015-12-13.
  54. Arendt, Wayne J. (1 January 1988). "Range Expansion of the Cattle Egret, (Bubulcus ibis) in the Greater Caribbean Basin". Colonial Waterbirds. 11 (2): 252–62. doi:10.2307/1521007. JSTOR 1521007.
  55. Bierregaard, R.O. (1994). "Yellow-headed Caracara". In Josep del Hoyo, Andrew Elliott and Jordi Sargatal (eds.). Handbook of the Birds of the World. Volume 2; New World Vultures to Guineafowl. Barcelona: Lynx Edicions. ISBN 84-87334-15-6.
  56. Juniper, Tony; Mike Parr (1998). Parrots: A Guide to the Parrots of the World. London: Christopher Helm. ISBN 0-7136-6933-0.
  57. Ehrlich, Paul R.; David S. Dobkin; Darryl Wheye (1988). "Adaptations for Flight". Birds of Stanford. Stanford University. Retrieved 13 December 2007. Based on The Birder's Handbook (Paul Ehrlich, David Dobkin, and Darryl Wheye. 1988. Simon and Schuster, New York.)
  58. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 Gill, Frank (1995). Ornithology. New York: WH Freeman and Co. ISBN 0-7167-2415-4.
  59. Noll, Paul. "The Avian Skeleton". paulnoll.com. Retrieved 13 December 2007.
  60. "Skeleton of a typical bird". Fernbank Science Center's Ornithology Web. Retrieved 13 December 2007.
  61. Ehrlich, Paul R.; David S. Dobkin; Darryl Wheye (1988). "Drinking". Birds of Stanford. Stanford University. Retrieved 13 December 2007.
  62. Tsahar, Ella; Martínez Del Rio, C; Izhaki, I; Arad, Z (2005). "Can birds be ammonotelic? Nitrogen balance and excretion in two frugivores". Journal of Experimental Biology. 208 (6): 1025–34. doi:10.1242/jeb.01495. PMID 15767304.
  63. Skadhauge, E; Erlwanger, KH; Ruziwa, SD; Dantzer, V; Elbrønd, VS; Chamunorwa, JP (2003). "Does the ostrich (Struthio camelus) coprodeum have the electrophysiological properties and microstructure of other birds?". Comparative Biochemistry and Physiology A. 134 (4): 749–755. doi:10.1016/S1095-6433(03)00006-0. PMID 12814783.
  64. Preest, Marion R.; Beuchat, Carol A. (April 1997). "Ammonia excretion by hummingbirds". Nature. 386 (6625): 561–62. doi:10.1038/386561a0.
  65. Mora, J.; Martuscelli, J; Ortiz Pineda, J; Soberon, G (1965). "The regulation of urea-biosynthesis enzymes in vertebrates" (PDF). Biochemical Journal. 96 (1): 28–35. PMC 1206904Freely accessible. PMID 14343146.
  66. Packard, Gary C. (1966). "The Influence of Ambient Temperature and Aridity on Modes of Reproduction and Excretion of Amniote Vertebrates". The American Naturalist. 100 (916): 667–82. doi:10.1086/282459. JSTOR 2459303.
  67. Balgooyen, Thomas G. (1 October 1971). "Pellet Regurgitation by Captive Sparrow Hawks (Falco sparverius)" (PDF). Condor. 73 (3): 382–85. doi:10.2307/1365774. JSTOR 1365774. Archived from the original (PDF) on 24 May 2013.
  68. Yong, Ed. "Phenomena: Not Exactly Rocket Science How Chickens Lost Their Penises (And Ducks Kept Theirs)". Phenomena.nationalgeographic.com. Retrieved 3 October 2013.
  69. "Ornithology, 3rd Edition - Waterfowl: Order Anseriformes". Retrieved 3 October 2013.
  70. McCracken, KG (2000). "The 20-cm Spiny Penis of the Argentine Lake Duck (Oxyura vittata)" (PDF). The Auk. 117 (3): 820–825. doi:10.1642/0004-8038(2000)117[0820:TCSPOT]2.0.CO;2. Archived from the original (PDF) on 24 May 2013.
  71. Gionfriddo, James P.; Best (1 February 1995). "Grit Use by House Sparrows: Effects of Diet and Grit Size" (PDF). Condor. 97 (1): 57–67. doi:10.2307/1368983.
  72. 1 2 3 Attenborough, David (1998). The Life of Birds. Princeton: Princeton University Press. ISBN 0-691-01633-X.
  73. 1 2 Battley, Phil F.; Piersma, T; Dietz, MW; Tang, S; Dekinga, A; Hulsman, K (January 2000). "Empirical evidence for differential organ reductions during trans-oceanic bird flight". Proceedings of the Royal Society B. 267 (1439): 191–5. doi:10.1098/rspb.2000.0986. PMC 1690512Freely accessible. PMID 10687826. (Erratum in Proceedings of the Royal Society B 267(1461):2567.)
  74. Maina, John N. (November 2006). "Development, structure, and function of a novel respiratory organ, the lung-air sac system of birds: to go where no other vertebrate has gone". Biological Reviews. 81 (4): 545–79. doi:10.1017/S1464793106007111. PMID 17038201.
  75. 1 2 Suthers, Roderick A.; Sue Anne Zollinger (2004). "Producing song: the vocal apparatus". In H. Philip Zeigler and Peter Marler (eds.). Behavioral Neurobiology of Birdsong. Annals of the New York Academy of Sciences 1016. New York: New York Academy of Sciences. pp. 109–129. doi:10.1196/annals.1298.041. ISBN 1-57331-473-0. PMID 15313772
  76. Fitch, W. T. (1999). "Acoustic exaggeration of size in birds via tracheal elongation: comparative and theoretical analyses". Journal of Zoology. 248: 31–48. doi:10.1017/S095283699900504X.
  77. Scott, Robert B. (March 1966). "Comparative hematology: The phylogeny of the erythrocyte". Annals of Hematology. 12 (6): 340–51. doi:10.1007/BF01632827. PMID 5325853.
  78. 1 2 Whittow, G. (2000). Sturkie's Avian Physiology/ edited by G. Causey Whittow. San Diego : Academic Press, 2000.
  79. 1 2 Hoagstrom, C.W. (2002). Vertebrate Circulation. Magill's Encyclopedia of Science: Animal Life. Vol 1, pp 217-219. Pasadena, California, Salem Press.
  80. 1 2 Hill, Richard W. (2012) Animal Physiology/ Richard W. Hill, Gordon A. Wyse, Margaret Anderson. Third Edition pp 647-678. Sinauer Associates, 23 Plumtree Road, Sunderland, MA 01375 USA
  81. Sales, James (2005). "The endangered kiwi: a review" (PDF). Folia Zoologica. 54 (1–2): 1–20.
  82. Ehrlich, Paul R.; David S. Dobkin; Darryl Wheye (1988). "The Avian Sense of Smell". Birds of Stanford. Stanford University. Retrieved 13 December 2007.
  83. Lequette, Benoit; Verheyden; Jouventin (1 August 1989). "Olfaction in Subantarctic seabirds: Its phylogenetic and ecological significance" (PDF). The Condor. 91 (3): 732–35. doi:10.2307/1368131. Archived from the original (PDF) on 23 February 2013.
  84. Wilkie, Susan E.; Vissers, PM; Das, D; Degrip, WJ; Bowmaker, JK; Hunt, DM (February 1998). "The molecular basis for UV vision in birds: spectral characteristics, cDNA sequence and retinal localization of the UV-sensitive visual pigment of the budgerigar (Melopsittacus undulatus)". Biochemical Journal. 330 (Pt 1): 541–47. PMC 1219171Freely accessible. PMID 9461554.
  85. Andersson, S.; J. Ornborg; M. Andersson (1998). "Ultraviolet sexual dimorphism and assortative mating in blue tits". Proceedings of the Royal Society B. 265 (1395): 445–50. doi:10.1098/rspb.1998.0315.
  86. Viitala, Jussi; Korplmäki, Erkki; Palokangas, Pälvl; Koivula, Minna (1995). "Attraction of kestrels to vole scent marks visible in ultraviolet light". Nature. 373 (6513): 425–27. doi:10.1038/373425a0.
  87. Williams, David L.; Flach, E (March 2003). "Symblepharon with aberrant protrusion of the nictitating membrane in the snowy owl (Nyctea scandiaca)". Veterinary Ophthalmology. 6 (1): 11–13. doi:10.1046/j.1463-5224.2003.00250.x. PMID 12641836.
  88. White, Craig R.; Day, N; Butler, PJ; Martin, GR; Bennett, Peter (July 2007). Bennett, Peter, ed. "Vision and Foraging in Cormorants: More like Herons than Hawks?". PLoS ONE. 2 (7): e639. doi:10.1371/journal.pone.0000639. PMC 1919429Freely accessible. PMID 17653266.
  89. Martin, Graham R.; Katzir, G (1999). "Visual fields in Short-toed Eagles, Circaetus gallicus (Accipitridae), and the function of binocularity in birds". Brain, Behaviour and Evolution. 53 (2): 55–66. doi:10.1159/000006582. PMID 9933782.
  90. Saito, Nozomu (1978). "Physiology and anatomy of avian ear". The Journal of the Acoustical Society of America. 64 (S1): S3. doi:10.1121/1.2004193.
  91. Warham, John (1 May 1977). "The incidence, function and ecological significance of petrel stomach oils" (PDF). Proceedings of the New Zealand Ecological Society. 24 (3): 84–93.
  92. Dumbacher, J.P.; Beehler, BM; Spande, TF; Garraffo, HM; Daly, JW (October 1992). "Homobatrachotoxin in the genus Pitohui: chemical defense in birds?". Science. 258 (5083): 799–801. doi:10.1126/science.1439786. PMID 1439786.
  93. 1 2 3 Longrich, N. R.; Olson, S. L. (5 January 2011). "The bizarre wing of the Jamaican flightless ibis Xenicibis xympithecus: a unique vertebrate adaptation". Proceedings of the Royal Society B: Biological Sciences. 278 (1716): 2333–2337. doi:10.1098/rspb.2010.2117. Retrieved 12 November 2015.
  94. Göth, Anne (2007). "Incubation temperatures and sex ratios in Australian brush-turkey (Alectura lathami) mounds". Austral Ecology. 32 (4): 278–85. doi:10.1111/j.1442-9993.2007.01709.x.
  95. Göth, A; Booth, DT (March 2005). "Temperature-dependent sex ratio in a bird". Biology Letters. 1: 31–3. doi:10.1098/rsbl.2004.0247. PMC 1629050Freely accessible. PMID 17148121.
  96. Belthoff, James R.; Dufty,; Gauthreaux, (1 August 1994). "Plumage Variation, Plasma Steroids and Social Dominance in Male House Finches". The Condor. 96 (3): 614–25. doi:10.2307/1369464.
  97. Guthrie, R. Dale. "How We Use and Show Our Social Organs". Body Hot Spots: The Anatomy of Human Social Organs and Behavior. Archived from the original on 21 June 2007. Retrieved 19 October 2007.
  98. Humphrey, Philip S.; Parkes, K. C. (1 June 1959). "An approach to the study of molts and plumages" (PDF). The Auk. 76 (1): 1–31. doi:10.2307/4081839. JSTOR 4081839.
  99. 1 2 3 Pettingill Jr. OS (1970). Ornithology in Laboratory and Field. Burgess Publishing Co. ISBN 0-12-552455-2.
  100. de Beer SJ, Lockwood GM, Raijmakers JHFS, Raijmakers JMH, Scott WA, Oschadleus HD, Underhill LG (2001). "SAFRING Bird Ringing Manual".
  101. Gargallo, Gabriel (1 June 1994). "Flight Feather Moult in the Red-Necked Nightjar Caprimulgus ruficollis". Journal of Avian Biology. 25 (2): 119–24. doi:10.2307/3677029. JSTOR 3677029.
  102. Mayr, Ernst (1954). "The tail molt of small owls" (PDF). The Auk. 71 (2): 172–78. doi:10.2307/4081571. Archived from the original (PDF) on 24 May 2013.
  103. Payne, Robert B. "Birds of the World, Biology 532". Bird Division, University of Michigan Museum of Zoology. Retrieved 20 October 2007.
  104. Turner, J. Scott (1997). "On the thermal capacity of a bird's egg warmed by a brood patch". Physiological Zoology. 70 (4): 470–80. doi:10.1086/515854. PMID 9237308.
  105. Walther, Bruno A. (2005). "Elaborate ornaments are costly to maintain: evidence for high maintenance handicaps". Behavioural Ecology. 16 (1): 89–95. doi:10.1093/beheco/arh135.
  106. Shawkey, Matthew D.; Pillai, Shreekumar R.; Hill, Geoffrey E. (2003). "Chemical warfare? Effects of uropygial oil on feather-degrading bacteria". Journal of Avian Biology. 34 (4): 345–49. doi:10.1111/j.0908-8857.2003.03193.x.
  107. Ehrlich, Paul R. (1986). "The Adaptive Significance of Anting" (PDF). The Auk. 103 (4): 835. Archived from the original (PDF) on 24 May 2013.
  108. Lucas, Alfred M. (1972). Avian Anatomy—integument. East Lansing, Michigan, US: USDA Avian Anatomy Project, Michigan State University. pp. 67, 344, 394–601.
  109. Roots, Clive (2006). Flightless Birds. Westport: Greenwood Press. ISBN 978-0-313-33545-7.
  110. McNab, Brian K. (October 1994). "Energy Conservation and the Evolution of Flightlessness in Birds". The American Naturalist. 144 (4): 628–42. doi:10.1086/285697. JSTOR 2462941.
  111. Kovacs, Christopher E.; Meyers, RA (2000). "Anatomy and histochemistry of flight muscles in a wing-propelled diving bird, the Atlantic Puffin, Fratercula arctica". Journal of Morphology. 244 (2): 109–25. doi:10.1002/(SICI)1097-4687(200005)244:2<109::AID-JMOR2>3.0.CO;2-0. PMID 10761049.
  112. Robert, Michel; McNeil, Raymond; Leduc, Alain (January 1989). "Conditions and significance of night feeding in shorebirds and other water birds in a tropical lagoon" (PDF). The Auk. 106 (1): 94–101. doi:10.2307/4087761. Archived from the original (PDF) on 24 May 2013.
  113. "How Do Birds Eat If They Have No Teeth? | Blog | eNature". wild.enature.com. Retrieved 2016-03-30.
  114. N Reid (2006). "Birds on New England wool properties – A woolgrower guide" (PDF). Land, Water & Wool Northern Tablelands Property Fact Sheet. Australian Government – Land and Water Australia. Archived from the original (PDF) on 15 March 2011. Retrieved 17 July 2010.
  115. Paton, D. C.; Collins, B. G. (1 April 1989). "Bills and tongues of nectar-feeding birds: A review of morphology, function, and performance, with intercontinental comparisons". Australian Journal of Ecology. 14 (4): 473–506. doi:10.1111/j.1442-9993.1989.tb01457.x.
  116. Baker, Myron Charles; Baker, Ann Eileen Miller (1 April 1973). "Niche Relationships Among Six Species of Shorebirds on Their Wintering and Breeding Ranges". Ecological Monographs. 43 (2): 193–212. doi:10.2307/1942194. JSTOR 1942194.
  117. Cherel, Yves; Bocher, P; De Broyer, C; Hobson, KA (2002). "Food and feeding ecology of the sympatric thin-billed Pachyptila belcheri and Antarctic P. desolata prions at Iles Kerguelen, Southern Indian Ocean". Marine Ecology Progress Series. 228: 263–81. doi:10.3354/meps228263.
  118. Jenkin, Penelope M. (1957). "The Filter-Feeding and Food of Flamingoes (Phoenicopteri)". Philosophical Transactions of the Royal Society B. 240 (674): 401–93. doi:10.1098/rstb.1957.0004. JSTOR 92549.
  119. Miyazaki, Masamine; Kuroki, M.; Niizuma, Y.; Watanuki, Y. (1 July 1996). "Vegetation cover, kleptoparasitism by diurnal gulls and timing of arrival of nocturnal Rhinoceros Auklets" (PDF). The Auk. 113 (3): 698–702. doi:10.2307/3677021. JSTOR 3677021. Archived from the original (PDF) on 24 May 2013.
  120. Bélisle, Marc; Giroux (1 August 1995). "Predation and kleptoparasitism by migrating Parasitic Jaegers" (PDF). The Condor. 97 (3): 771–781. doi:10.2307/1369185.
  121. Vickery, J. A.; Brooke, M. De L. (1 May 1994). "The Kleptoparasitic Interactions between Great Frigatebirds and Masked Boobies on Henderson Island, South Pacific" (PDF). The Condor. 96 (2): 331–40. doi:10.2307/1369318. JSTOR 1369318. Archived from the original (PDF) on 24 May 2013.
  122. Hiraldo, F.C.; Blanco, J. C.; Bustamante, J. (1991). "Unspecialized exploitation of small carcasses by birds". Bird Studies. 38 (3): 200–07. doi:10.1080/00063659109477089.
  123. Engel, Sophia Barbara (2005). Racing the wind: Water economy and energy expenditure in avian endurance flight. University of Groningen. ISBN 90-367-2378-7.
  124. Tieleman, B.I.; Williams, JB (1999). "The role of hyperthermia in the water economy of desert birds". Physiol. Biochem. Zool. 72 (1): 87–100. doi:10.1086/316640. PMID 9882607.
  125. Schmidt-Nielsen, Knut (1 May 1960). "The Salt-Secreting Gland of Marine Birds". Circulation. 21 (5): 955–967. doi:10.1161/01.CIR.21.5.955.
  126. Hallager, Sara L. (1994). "Drinking methods in two species of bustards". Wilson Bull. 106 (4): 763–764. hdl:10088/4338.
  127. MacLean, Gordon L. (1 June 1983). "Water Transport by Sandgrouse". BioScience. 33 (6): 365–369. doi:10.2307/1309104. JSTOR 1309104.
  128. Eraud C; Dorie A; Jacquet A; Faivre B (2008). "The crop milk: a potential new route for carotenoid-mediated parental effects". Journal of Avian Biology. 39 (2): 247–251. doi:10.1111/j.0908-8857.2008.04053.x.
  129. Mario, Principato; Federica, Lisi; Iolanda, Moretta; Nada, Samra; Francesco, Puccetti (2005). "The alterations of plumage of parasitic origin". Italian Journal of Animal Science. 4: 296–299.
  130. Revis, Hannah C.; Waller, Deborah A. (2004). "Bactericidal and fungicidal activity of ant chemicals on feather parasites: an evaluation of anting behavior as a method of self-medication in songbirds". The Auk. 121 (4): 1262–1268. doi:10.1642/0004-8038(2004)121[1262:BAFAOA]2.0.CO;2.
  131. Clayton, Dale H.; Koop, Jennifer A. H.; Harbison, Christopher W.; Moyer, Brett R.; Bush, Sarah E. (2010). "How Birds Combat Ectoparasites" (PDF). The Open Ornithology Journal. 3: 41–71. doi:10.2174/1874453201003010041.
  132. Klaassen, Marc (1 January 1996). "Metabolic constraints on long-distance migration in birds". Journal of Experimental Biology. 199 (1): 57–64. PMID 9317335.
  133. Gill, Frank (1995). Ornithology (2nd ed.). New York: W.H. Freeman. ISBN 0-7167-2415-4.
  134. "Long-distance Godwit sets new record". BirdLife International. 4 May 2007. Retrieved 13 December 2007.
  135. Shaffer, Scott A.; Tremblay, Y; Weimerskirch, H; Scott, D; Thompson, DR; Sagar, PM; Moller, H; Taylor, GA; Foley, DG; et al. (2006). "Migratory shearwaters integrate oceanic resources across the Pacific Ocean in an endless summer". Proceedings of the National Academy of Sciences of the United States of America. 103 (34): 12799–802. doi:10.1073/pnas.0603715103. PMC 1568927Freely accessible. PMID 16908846.
  136. Croxall, John P.; Silk, JR; Phillips, RA; Afanasyev, V; Briggs, DR (2005). "Global Circumnavigations: Tracking year-round ranges of nonbreeding Albatrosses". Science. 307 (5707): 249–50. doi:10.1126/science.1106042. PMID 15653503.
  137. Wilson, W. Herbert, Jr. (1999). "Bird feeding and irruptions of northern finches:are migrations short stopped?" (PDF). North America Bird Bander. 24 (4): 113–21. Archived from the original (PDF) on 24 May 2013.
  138. Nilsson, Anna L. K.; Alerstam, Thomas; Nilsson, Jan-Åke (2006). "Do partial and regular migrants differ in their responses to weather?". The Auk. 123 (2): 537–47. doi:10.1642/0004-8038(2006)123[537:DPARMD]2.0.CO;2.
  139. Chan, Ken (2001). "Partial migration in Australian landbirds: a review". Emu. 101 (4): 281–92. doi:10.1071/MU00034.
  140. Rabenold, Kerry N. (1985). "Variation in Altitudinal Migration, Winter Segregation, and Site Tenacity in two subspecies of Dark-eyed Juncos in the southern Appalachians" (PDF). The Auk. 102 (4): 805–19.
  141. Collar, Nigel J. (1997). "Family Psittacidae (Parrots)". In Josep del Hoyo, Andrew Elliott and Jordi Sargatal (eds.). Handbook of the Birds of the World, Volume 4: Sandgrouse to Cuckoos. Barcelona: Lynx Edicions. ISBN 84-87334-22-9.
  142. Matthews, G. V. T. (1 September 1953). "Navigation in the Manx Shearwater". Journal of Experimental Biology. 30 (2): 370–96.
  143. Mouritsen, Henrik; L (15 November 2001). "Migrating songbirds tested in computer-controlled Emlen funnels use stellar cues for a time-independent compass". Journal of Experimental Biology. 204 (8): 3855–65. PMID 11807103.
  144. Deutschlander, Mark E.; P; B (15 April 1999). "The case for light-dependent magnetic orientation in animals". Journal of Experimental Biology. 202 (8): 891–908. PMID 10085262.
  145. Möller, Anders Pape (1988). "Badge size in the house sparrow Passer domesticus". Behavioral Ecology and Sociobiology. 22 (5): 373–78. doi:10.1007/BF00295107.
  146. Thomas, Betsy Trent; Strahl (1 August 1990). "Nesting Behavior of Sunbitterns (Eurypyga helias) in Venezuela" (PDF). The Condor. 92 (3): 576–81. doi:10.2307/1368675. Archived from the original (PDF) on 24 May 2013.
  147. Pickering, S. P. C. (2001). "Courtship behaviour of the Wandering Albatross Diomedea exulans at Bird Island, South Georgia" (PDF). Marine Ornithology. 29 (1): 29–37.
  148. Pruett-Jones, S. G.; Pruett-Jones (1 May 1990). "Sexual Selection Through Female Choice in Lawes' Parotia, A Lek-Mating Bird of Paradise". Evolution. 44 (3): 486–501. doi:10.2307/2409431.
  149. Genevois, F.; Bretagnolle, V. (1994). "Male Blue Petrels reveal their body mass when calling". Ethology Ecology and Evolution. 6 (3): 377–83. doi:10.1080/08927014.1994.9522988.
  150. Jouventin, Pierre; Aubin, T; Lengagne, T (June 1999). "Finding a parent in a king penguin colony: the acoustic system of individual recognition". Animal Behaviour. 57 (6): 1175–83. doi:10.1006/anbe.1999.1086. PMID 10373249.
  151. Templeton, Christopher N.; Greene, E; Davis, K (2005). "Allometry of Alarm Calls: Black-Capped Chickadees Encode Information About Predator Size". Science. 308 (5730): 1934–37. doi:10.1126/science.1108841. PMID 15976305.
  152. Miskelly, C. M. (July 1987). "The identity of the hakawai". Notornis. 34 (2): 95–116.
  153. Murphy, Stephen; Legge, Sarah; Heinsohn, Robert (2003). "The breeding biology of palm cockatoos (Probosciger aterrimus): a case of a slow life history". Journal of Zoology. 261 (4): 327–39. doi:10.1017/S0952836903004175.
  154. 1 2 Sekercioglu, Cagan Hakki (2006). "Foreword". In Josep del Hoyo, Andrew Elliott and David Christie (eds.). Handbook of the Birds of the World, Volume 11: Old World Flycatchers to Old World Warblers. Barcelona: Lynx Edicions. p. 48. ISBN 84-96553-06-X.
  155. Terborgh, John (2005). "Mixed flocks and polyspecific associations: Costs and benefits of mixed groups to birds and monkeys". American Journal of Primatology. 21 (2): 87–100. doi:10.1002/ajp.1350210203.
  156. Hutto, Richard L. (January 1988). "Foraging Behavior Patterns Suggest a Possible Cost Associated with Participation in Mixed-Species Bird Flocks". Oikos. 51 (1): 79–83. doi:10.2307/3565809. JSTOR 3565809.
  157. Au, David W. K.; Pitman (1 August 1986). "Seabird interactions with Dolphins and Tuna in the Eastern Tropical Pacific" (PDF). The Condor. 88 (3): 304–17. doi:10.2307/1368877.
  158. Anne, O.; Rasa, E. (June 1983). "Dwarf mongoose and hornbill mutualism in the Taru desert, Kenya". Behavioral Ecology and Sociobiology. 12 (3): 181–90. doi:10.1007/BF00290770.
  159. Gauthier-Clerc, Michael; Tamisier, Alain; Cézilly, Frank (2000). "Sleep-Vigilance Trade-off in Gadwall during the Winter Period" (PDF). The Condor. 102 (2): 307–13. doi:10.1650/0010-5422(2000)102[0307:SVTOIG]2.0.CO;2. JSTOR 1369642. Archived from the original (PDF) on 27 December 2004.
  160. Bäckman, Johan; A (1 April 2002). "Harmonic oscillatory orientation relative to the wind in nocturnal roosting flights of the swift Apus apus". The Journal of Experimental Biology. 205 (7): 905–910. PMID 11916987.
  161. Rattenborg, Niels C. (2006). "Do birds sleep in flight?". Die Naturwissenschaften. 93 (9): 413–25. doi:10.1007/s00114-006-0120-3. PMID 16688436.
  162. Milius, S. (6 February 1999). "Half-asleep birds choose which half dozes". Science News Online. 155 (6): 86. doi:10.2307/4011301. JSTOR 4011301.
  163. Beauchamp, Guy (1999). "The evolution of communal roosting in birds: origin and secondary losses". Behavioural Ecology. 10 (6): 675–87. doi:10.1093/beheco/10.6.675.
  164. Buttemer, William A. (1985). "Energy relations of winter roost-site utilization by American goldfinches (Carduelis tristis)" (PDF). Oecologia. 68 (1): 126–32. doi:10.1007/BF00379484.
  165. Buckley, F. G.; Buckley (1 January 1968). "Upside-down Resting by Young Green-Rumped Parrotlets (Forpus passerinus)". The Condor. 70 (1): 89. doi:10.2307/1366517.
  166. Carpenter, F. Lynn (1974). "Torpor in an Andean Hummingbird: Its Ecological Significance". Science. 183 (4124): 545–47. doi:10.1126/science.183.4124.545. PMID 17773043.
  167. McKechnie, Andrew E.; Ashdown, Robert A. M.; Christian, Murray B.; Brigham, R. Mark (2007). "Torpor in an African caprimulgid, the freckled nightjar Caprimulgus tristigma". Journal of Avian Biology. 38 (3): 261–66. doi:10.1111/j.2007.0908-8857.04116.x.
  168. Frith, C.B (1981). "Displays of Count Raggi's Bird-of-Paradise Paradisaea raggiana and congeneric species". Emu. 81 (4): 193–201. doi:10.1071/MU9810193.
  169. Freed, Leonard A. (1987). "The Long-Term Pair Bond of Tropical House Wrens: Advantage or Constraint?". The American Naturalist. 130 (4): 507–25. doi:10.1086/284728.
  170. Gowaty, Patricia A. (1983). "Male Parental Care and Apparent Monogamy among Eastern Bluebirds (Sialia sialis)". The American Naturalist. 121 (2): 149–60. doi:10.1086/284047.
  171. Westneat, David F.; Stewart, Ian R.K. (2003). "Extra-pair paternity in birds: Causes, correlates, and conflict". Annual Review of Ecology, Evolution, and Systematics. 34: 365–96. doi:10.1146/annurev.ecolsys.34.011802.132439.
  172. Gowaty, Patricia A.; Buschhaus, Nancy (1998). "Ultimate causation of aggressive and forced copulation in birds: Female resistance, the CODE hypothesis, and social monogamy". American Zoologist. 38 (1): 207–25. doi:10.1093/icb/38.1.207.
  173. Birkhead, T.R.; Møller, P. (1993). "Sexual selection and the temporal separation of reproductive events: sperm storage data from reptiles, birds and mammals". Biological Journal of the Linnean Society. 50: 295–311. doi:10.1111/j.1095-8312.1993.tb00933.x.
  174. Sheldon, B (1994). "Male Phenotype, Fertility, and the Pursuit of Extra-Pair Copulations by Female Birds". Proceedings of the Royal Society B. 257 (1348): 25–30. doi:10.1098/rspb.1994.0089.
  175. Wei, G; Zuo-Hua, Yin; Fu-Min, Lei (2005). "Copulations and mate guarding of the Chinese Egret". Waterbirds. 28 (4): 527–30. doi:10.1675/1524-4695(2005)28[527:CAMGOT]2.0.CO;2.
  176. Short, Lester L. (1993). Birds of the World and their Behavior. New York: Henry Holt and Co. ISBN 0-8050-1952-9.
  177. Burton, R (1985). Bird Behavior. Alfred A. Knopf, Inc. ISBN 0-394-53957-5.
  178. Schamel, D; Tracy, Diane M.; Lank, David B.; Westneat, David F. (2004). "Mate guarding, copulation strategies and paternity in the sex-role reversed, socially polyandrous red-necked phalarope Phalaropus lobatus" (PDF). Behaviour Ecology and Sociobiology. 57 (2): 110–18. doi:10.1007/s00265-004-0825-2.
  179. Bagemihl, Bruce. Biological exuberance: Animal homosexuality and natural diversity. New York: St. Martin's, 1999. pp. 479–655. One hundred species are described in detail.
  180. Kokko, H; Harris, M; Wanless, S (2004). "Competition for breeding sites and site-dependent population regulation in a highly colonial seabird, the common guillemot Uria aalge". Journal of Animal Ecology. 73 (2): 367–76. doi:10.1111/j.0021-8790.2004.00813.x.
  181. Booker, L; Booker, M (1991). "Why Are Cuckoos Host Specific?". Oikos. 57 (3): 301–09. doi:10.2307/3565958. JSTOR 3565958.
  182. 1 2 Hansell M (2000). Bird Nests and Construction Behaviour. University of Cambridge Press ISBN 0-521-46038-7
  183. Lafuma, L; Lambrechts, M; Raymond, M (2001). "Aromatic plants in bird nests as a protection against blood-sucking flying insects?". Behavioural Processes. 56 (2): 113–20. doi:10.1016/S0376-6357(01)00191-7.
  184. Warham, J. (1990) The Petrels: Their Ecology and Breeding Systems London: Academic Press ISBN 0-12-735420-4.
  185. Jones DN, Dekker, René WRJ, Roselaar, Cees S (1995). The Megapodes. Bird Families of the World 3. Oxford University Press: Oxford. ISBN 0-19-854651-3
  186. "AnAge: The animal ageing and longevity database". Human Ageing and Genomics Resources. Retrieved 26 September 2014.
  187. "Animal diversity web". University of Michigan, Museum of Zoology. Retrieved 26 September 2014.
  188. Elliot A (1994). "Family Megapodiidae (Megapodes)" in Handbook of the Birds of the World. Volume 2; New World Vultures to Guineafowl (eds del Hoyo J, Elliott A, Sargatal J) Lynx Edicions:Barcelona. ISBN 84-87334-15-6
  189. Metz VG, Schreiber EA (2002). "Great Frigatebird (Fregata minor)" In The Birds of North America, No 681, (Poole, A. and Gill, F., eds) The Birds of North America Inc: Philadelphia
  190. Young, Euan. Skua and Penguin. Predator and Prey.. Cambridge University Press, 1994, p. 453.
  191. Ekman, J (2006). "Family living amongst birds". Journal of Avian Biology. 37 (4): 289–98. doi:10.1111/j.2006.0908-8857.03666.x.
  192. Cockburn A (1996). "Why do so many Australian birds cooperate? Social evolution in the Corvida". In Floyd R, Sheppard A, de Barro P. Frontiers in Population Ecology. Melbourne: CSIRO. pp. 21–42.
  193. Cockburn, Andrew (2006). "Prevalence of different modes of parental care in birds". Proceedings of the Royal Society B. 273 (1592): 1375–83. doi:10.1098/rspb.2005.3458. PMC 1560291Freely accessible. PMID 16777726.
  194. Gaston AJ (1994). Ancient Murrelet (Synthliboramphus antiquus). In The Birds of North America, No. 132 (A. Poole and F. Gill, Eds.). Philadelphia: The Academy of Natural Sciences; Washington, D.C.: The American Ornithologists' Union.
  195. Schaefer, HC; Eshiamwata, GW; Munyekenye, FB; Böhning-Gaese, K (2004). "Life-history of two African Sylvia warblers: low annual fecundity and long post-fledging care". Ibis. 146 (3): 427–37. doi:10.1111/j.1474-919X.2004.00276.x.
  196. Alonso, JC; Bautista, LM; Alonso, JA (2004). "Family-based territoriality vs flocking in wintering common cranes Grus grus". Journal of Avian Biology. 35 (5): 434–44. doi:10.1111/j.0908-8857.2004.03290.x.
  197. 1 2 Davies N (2000). Cuckoos, Cowbirds and other Cheats. T. & A. D. Poyser: London ISBN 0-85661-135-2
  198. Sorenson, M (1997). "Effects of intra- and interspecific brood parasitism on a precocial host, the canvasback, Aythya valisineria" (PDF). Behavioral Ecology. 8 (2): 153–61. doi:10.1093/beheco/8.2.153.
  199. Spottiswoode, C. N.; Colebrook-Robjent, J. F.R. (2007). "Egg puncturing by the brood parasitic Greater Honeyguide and potential host counteradaptations". Behavioral Ecology. 18 (4): 792–799. doi:10.1093/beheco/arm025.
  200. Edwards, DB (2012). "Immune investment is explained by sexual selection and pace-of-life, but not longevity in parrots (Psittaciformes).". PLOS ONE. 7 (12): e53066. doi:10.1371/journal.pone.0053066. PMC 3531452Freely accessible. PMID 23300862.
  201. Doutrelant, C; Grégoire, A; Midamegbe, A; Lambrechts, M; Perret, P (January 2012). "Female plumage coloration is sensitive to the cost of reproduction. An experiment in blue tits.". Journal of Animal Ecology. 81 (1): 87–96. doi:10.1111/j.1365-2656.2011.01889.x. PMID 21819397.
  202. Hemmings NL, Slate J, Birkhead TR (2012). "Inbreeding causes early death in a passerine bird". Nat Commun. 3: 863. doi:10.1038/ncomms1870. PMID 22643890.
  203. Keller LF, Grant PR, Grant BR, Petren K (2002). "Environmental conditions affect the magnitude of inbreeding depression in survival of Darwin's finches". Evolution. 56 (6): 1229–39. doi:10.1111/j.0014-3820.2002.tb01434.x. PMID 12144022.
  204. 1 2 Kingma, SA; Hall, ML; Peters, A (2013). "Breeding synchronization facilitates extrapair mating for inbreeding avoidance". Behavioral Ecology. 24 (6): 1390–1397. doi:10.1093/beheco/art078.
  205. Szulkin M, Sheldon BC (2008). "Dispersal as a means of inbreeding avoidance in a wild bird population". Proc. Biol. Sci. 275 (1635): 703–11. doi:10.1098/rspb.2007.0989. PMC 2596843Freely accessible. PMID 18211876.
  206. Nelson-Flower MJ, Hockey PA, O'Ryan C, Ridley AR (2012). "Inbreeding avoidance mechanisms: dispersal dynamics in cooperatively breeding southern pied babblers". J Anim Ecol. 81 (4): 876–83. doi:10.1111/j.1365-2656.2012.01983.x. PMID 22471769.
  207. Riehl C, Stern CA (2015). "How cooperatively breeding birds identify relatives and avoid incest: New insights into dispersal and kin recognition". BioEssays. 37 (12): 1303–8. doi:10.1002/bies.201500120. PMID 26577076.
  208. Charlesworth D, Willis JH (2009). "The genetics of inbreeding depression". Nat. Rev. Genet. 10 (11): 783–96. doi:10.1038/nrg2664. PMID 19834483.
  209. Bernstein H, Hopf FA, Michod RE (1987). "The molecular basis of the evolution of sex". Adv. Genet. 24: 323–70. doi:10.1016/s0065-2660(08)60012-7. PMID 3324702.
  210. Michod, R.E. (1994). "Eros and Evolution: A Natural Philosophy of Sex" Addison-Wesley Publishing Company, Reading, Massachusetts. ISBN 978-0201442328
  211. 1 2 Clout, M; Hay, J (1989). "The importance of birds as browsers, pollinators and seed dispersers in New Zealand forests" (PDF). New Zealand Journal of Ecology. 12: 27–33.
  212. Gary Stiles, F. (1981). "Geographical Aspects of Bird-Flower Coevolution, with Particular Reference to Central America". Annals of the Missouri Botanical Garden. 68 (2): 323–51. doi:10.2307/2398801. JSTOR 2398801.
  213. Temeles, E; Linhart, Y; Masonjones, M; Masonjones, H (2002). "The Role of Flower Width in Hummingbird Bill Length–Flower Length Relationships" (PDF). Biotropica. 34 (1): 68–80. doi:10.1111/j.1744-7429.2002.tb00243.x.
  214. Bond, William J.; Lee, William G.; Craine, Joseph M. (2004). "Plant structural defences against browsing birds: a legacy of New Zealand's extinct moas". Oikos. 104 (3): 500–08. doi:10.1111/j.0030-1299.2004.12720.x.
  215. Wainright, S; Haney, J; Kerr, C; Golovkin, A; Flint, M (1998). "Utilization of nitrogen derived from seabird guano by terrestrial and marine plants at St. Paul, Pribilof Islands, Bering Sea, Alaska" (PDF). Marine Ecology. 131 (1): 63–71. doi:10.1007/s002270050297.
  216. Bosman, A; Hockey, A (1986). "Seabird guano as a determinant of rocky intertidal community structure" (PDF). Marine Ecology Progress Series. 32: 247–57. doi:10.3354/meps032247.
  217. Bonney, Rick; Rohrbaugh, Jr., Ronald (2004). Handbook of Bird Biology (Second ed.). Princeton, NJ: Princeton University Press. ISBN 0-938027-62-X.
  218. Dean W, Siegfried R, MacDonald I (1990). "The Fallacy, Fact, and Fate of Guiding Behavior in the Greater Honeyguide". Conservation Biology 4 (1) 99–101. Blackwell-PDF
  219. Singer, R.; Yom-Tov, Y. (1988). "The Breeding Biology of the House Sparrow Passer domesticus in Israel". Ornis Scandinavica. 19 (2): 139–44. doi:10.2307/3676463. JSTOR 3676463.
  220. Dolbeer, R (1990). "Ornithology and integrated pest management: Red-winged blackbirds Agleaius phoeniceus and corn". Ibis. 132 (2): 309–22. doi:10.1111/j.1474-919X.1990.tb01048.x.
  221. Dolbeer, R; Belant, J; Sillings, J (1993). "Shooting Gulls Reduces Strikes with Aircraft at John F. Kennedy International Airport". Wildlife Society Bulletin. 21: 442–50.
  222. Reed, KD; Meece, JK; Henkel, JS; Shukla, SK (2003). "Birds, Migration and Emerging Zoonoses: West Nile Virus, Lyme Disease, Influenza A and Enteropathogens". Clinical medicine & research. 1 (1): 5–12. doi:10.3121/cmr.1.1.5. PMC 1069015Freely accessible. PMID 15931279.
  223. Brown, Lester (2005). "3: Moving Up the Food Chain Efficiently.". Outgrowing the Earth: The Food Security Challenge in an Age of Falling Water Tables and Rising Temperatures. earthscan. ISBN 978-1-84407-185-2.
  224. Simeone, A; Navarro, X (2002). "Human exploitation of seabirds in coastal southern Chile during the mid-Holocene". Rev. Chil. Hist. Nat. 75 (2): 423–31. doi:10.4067/S0716-078X2002000200012.
  225. Hamilton, S. (2000). "How precise and accurate are data obtained using. an infra-red scope on burrow-nesting sooty shearwaters Puffinus griseus?" (PDF). Marine Ornithology. 28 (1): 1–6.
  226. Keane, Aidan; Brooke, M.de L.; McGowan, P.J.K. (2005). "Correlates of extinction risk and hunting pressure in gamebirds (Galliformes)". Biological Conservation. 126 (2): 216–33. doi:10.1016/j.biocon.2005.05.011.
  227. "The Guano War of 1865–1866". World History at KMLA. Retrieved 18 December 2007.
  228. Cooney, R; Jepson, P (2006). "The international wild bird trade: what's wrong with blanket bans?". Oryx. 40 (1): 18–23. doi:10.1017/S0030605306000056.
  229. Manzi, M; Coomes, O. T. (2002). "Cormorant fishing in Southwestern China: a Traditional Fishery under Siege. (Geographical Field Note)". Geographic Review. 92 (4): 597–603. doi:10.2307/4140937. JSTOR 4140937.
  230. Pullis La Rouche, G. (2006). Birding in the United States: a demographic and economic analysis. Waterbirds around the world. Eds. G.C. Boere, C.A. Galbraith and D.A. Stroud. The Stationery Office, Edinburgh, UK. pp. 841–46. JNCC.gov.uk, PDF
  231. Chamberlain, DE; Vickery, JA; Glue, DE; Robinson, RA; Conway, GJ; Woodburn, RJW; Cannon, AR (2005). "Annual and seasonal trends in the use of garden feeders by birds in winter". Ibis. 147 (3): 563–75. doi:10.1111/j.1474-919x.2005.00430.x.
  232. Routledge, S; Routledge, K (1917). "The Bird Cult of Easter Island". Folklore. 28 (4): 337–55. doi:10.1080/0015587X.1917.9719006.
  233. Lukas, SE; Benedikt, R; Mendelson, JH; Kouri, E; Sholar, M; Amass, L (1992). "Marihuana attenuates the rise in plasma ethanol levels in human subjects". Neuropsychopharmacology. 7 (1): 77–81. PMID 1326277.
  234. Ingersoll, Ernest (1923). Archive.org, "Birds in legend, fable and folklore". Longmans, Green and co. p. 214
  235. Hauser, A. J. (1985). "Jonah: In Pursuit of the Dove". Journal of Biblical Literature. 104 (1): 21–37. doi:10.2307/3260591. JSTOR 3260591.
  236. Thankappan Nair, P. (1974). "The Peacock Cult in Asia". Asian Folklore Studies. 33 (2): 93–170. doi:10.2307/1177550. JSTOR 1177550.
  237. 1 2 Smith, S. (2011). "Generative landscapes: the step mountain motif in Tiwanaku iconography." (Automatic PDF download). Ancient America. 12: 1–69.
  238. Meighan, C. W. (1966). "Prehistoric Rock Paintings in Baja California". American Antiquity. 31 (3): 372–92. doi:10.2307/2694739. JSTOR 2694739.
  239. Tennyson A, Martinson P (2006). Extinct Birds of New Zealand Te Papa Press, Wellington ISBN 978-0-909010-21-8
  240. Clarke, CP (1908). "A Pedestal of the Platform of the Peacock Throne". The Metropolitan Museum of Art Bulletin. 3 (10): 182–83. doi:10.2307/3252550. JSTOR 3252550.
  241. Boime, Albert (1999). "John James Audubon: a birdwatcher's fanciful flights". Art History. 22 (5): 728–55. doi:10.1111/1467-8365.00184.
  242. Chandler, A (1934). "The Nightingale in Greek and Latin Poetry". The Classical Journal. 30 (2): 78–84. JSTOR 3289944.
  243. Lasky, E. D. (1992). "A Modern Day Albatross: The Valdez and Some of Life's Other Spills". The English Journal. 81 (3): 44–46. doi:10.2307/820195. JSTOR 820195.
  244. Carson, A (1998). "Vulture Investors, Predators of the 90s: An Ethical Examination" (PDF). Journal of Business Ethics. 17 (5): 543–55. doi:10.1023/A:1017974505642.
  245. Enriquez PL, Mikkola H (1997). "Comparative study of general public owl knowledge in Costa Rica, Central America and Malawi, Africa". pp. 160–66 In: J.R. Duncan, D.H. Johnson, T.H. Nicholls, (Eds). Biology and conservation of owls of the Northern Hemisphere. General Technical Report NC-190, USDA Forest Service, St. Paul, Minnesota. 635 pp.
  246. Lewis DP (2005). Owlpages.com, Owls in Mythology and Culture. Retrieved on 15 September 2007
  247. Dupree, N (1974). "An Interpretation of the Role of the Hoopoe in Afghan Folklore and Magic". Folklore. 85 (3): 173–93. doi:10.1080/0015587X.1974.9716553. JSTOR 1260073.
  248. Matthew Head (1997). "Birdsong and the Origins of Music". Journal of the Royal Musical Association. 122 (1): 1–23. doi:10.1093/jrma/122.1.1.
  249. Clark, Suzannah (2001). Music Theory and Natural Order from the Renaissance to the Early Twentieth Century. Cambridge University Press. ISBN 0-521-77191-9.
  250. Reich, Ronni (15 October 2010). "NJIT professor finds nothing cuckoo in serenading our feathered friends". Star Ledger. Retrieved 19 June 2011.
  251. Fuller E (2000). Extinct Birds (2nd ed.). Oxford University Press, Oxford, New York. ISBN 0-19-850837-9
  252. Steadman D (2006). Extinction and Biogeography in Tropical Pacific Birds, University of Chicago Press. ISBN 978-0-226-77142-7
  253. "BirdLife International announces more Critically Endangered birds than ever before". BirdLife International. 14 May 2009. Retrieved 15 May 2009.
  254. Kinver, Mark (13 May 2009). "Birds at risk reach record high". BBC News Online. Retrieved 15 May 2009.
  255. Norris K, Pain D (eds, 2002). Conserving Bird Biodiversity: General Principles and their Application Cambridge University Press. ISBN 978-0-521-78949-3
  256. Brothers, NP (1991). "Albatross mortality and associated bait loss in the Japanese longline fishery in the southern ocean". Biological Conservation. 55 (3): 255–68. doi:10.1016/0006-3207(91)90031-4.
  257. Wurster, D; Wurster, C; Strickland, W (1965). "Bird Mortality Following DDT Spray for Dutch Elm Disease". Ecology. 46 (4): 488–99. doi:10.2307/1934880.; Wurster, C. F.; Wurster, D. H.; Strickland, W. N. (1965). "Bird Mortality after Spraying for Dutch Elm Disease with DDT". Science. 148 (3666): 90–91. doi:10.1126/science.148.3666.90. PMID 14258730.
  258. Blackburn, T; Cassey, P; Duncan, R; Evans, K; Gaston, K (2004). "Avian Extinction and Mammalian Introductions on Oceanic Islands". Science. 305 (5692): 1955–58. doi:10.1126/science.1101617. PMID 15448269.
  259. Butchart, S; Stattersfield, A; Collar, N (2006). "How many bird extinctions have we prevented?" (PDF). Oryx. 40 (3): 266–79. doi:10.1017/S0030605306000950.

External links

Listen to this article (info/dl)


This audio file was created from a revision of the "Bird" article dated 2008-01-05, and does not reflect subsequent edits to the article. (Audio help)
More spoken articles

The Wikibook Dichotomous Key has a page on the topic of: Aves

This article is issued from Wikipedia - version of the 11/26/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.