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Bird nest

January 01, 1970

For animal nests in general, see Nest. For other uses, see Bird's nest.

A bird nest is the spot in which a bird lays and incubates its eggs and raises its young. Although the term popularly refers to a specific structure made by the bird itself—such as the grassy cup nest of the American robin or Eurasian blackbird, or the elaborately woven hanging nest of the Montezuma oropendola or the village weaver—that is too restrictive a definition. For some species, a nest is simply a shallow depression made in sand; for others, it is the knot-hole left by a broken branch, a burrow dug into the ground, a chamber drilled into a tree, an enormous rotting pile of vegetation and earth, a shelf made of dried saliva or a mud dome with an entrance tunnel. The smallest bird nests are those of some hummingbirds, tiny cups which can be a mere 2 cm (0.8 in) across and 2–3 cm (0.8–1.2 in) high.[1] At the other extreme, some nest mounds built by the dusky scrubfowl measure more than 11 m (36 ft) in diameter and stand nearly 5 m (16 ft) tall.[2] The study of birds' nests is known as caliology.

Deep cup nest of the great reed-warbler

Not all bird species build nests. Some species lay their eggs directly on the ground or rocky ledges, while brood parasites lay theirs in the nests of other birds, letting unwitting "foster parents" do the work of rearing the young. Although nests are primarily used for breeding, they may also be reused in the non-breeding season for roosting and some species build special dormitory nests or roost nests (or winter-nest) that are used only for roosting.[3] Most birds build a new nest each year, though some refurbish their old nests.[4] The large eyries (or aeries) of some eagles are platform nests that have been used and refurbished for several years.

In the majority of nest-building species the female does most or all of the nest construction, in others both partners contribute; sometimes the male builds the nest and the hen lines it.[5][6] In some polygynous species, however, the male does most or all of the nest building. The nest may also form a part of the courtship display such as in weaver birds. The ability to choose and maintain good nest sites and build high quality nests may be selected for by females in these species. In some species the young from previous broods may also act as helpers for the adults.

Type edit

 

Not every bird species builds or uses a nest. Some auks, for instance—including common murre, thick-billed murre and razorbill—lay their eggs directly onto the narrow rocky ledges they use as breeding sites.[7] The eggs of these species are dramatically pointed at one end, so that they roll in a circle when disturbed. This is critical for the survival of the developing eggs, as there are no nests to keep them from rolling off the side of the cliff. Presumably because of the vulnerability of their unprotected eggs, parent birds of these auk species rarely leave them unattended.[8] Nest location and architecture is strongly influenced by local topography and other abiotic factors.[9]

King penguins and emperor penguins also do not build nests; instead, they tuck their eggs and chicks between their feet and folds of skin on their lower bellies. They are thus able to move about while incubating, though in practice only the emperor penguin regularly does so. Emperor penguins breed during the harshest months of the Antarctic winter, and their mobility allows them to form huge huddled masses which help them to withstand the extremely high winds and low temperatures of the season. Without the ability to share body heat (temperatures in the centre of tight groups can be as much as 10C above the ambient air temperature), the penguins would expend far more energy trying to stay warm, and breeding attempts would probably fail.[10]

Some crevice-nesting species, including ashy storm-petrel, pigeon guillemot, Eurasian eagle-owl and Hume's tawny owl, lay their eggs in the relative shelter of a crevice in the rocks or a gap between boulders, but provide no additional nest material.[11][12] Potoos lay their single egg directly atop a broken stump, or into a shallow depression on a branch—typically where an upward-pointing branch died and fell off, leaving a small scar or knot-hole.[13] Brood parasites, such as the New World cowbirds, the honeyguides, and many of the Old World and Australasian cuckoos, lay their eggs in the active nests of other species.[14][15][16]

Scrape edit

 
Some nest linings, such as the shell fragments in this Charadrius plover scrape, may help to prevent the eggs from sinking into muddy or sandy soil.

The simplest nest construction is the scrape, which is merely a shallow depression in soil or vegetation.[17] This nest type, which typically has a rim deep enough to keep the eggs from rolling away, is sometimes lined with bits of vegetation, small stones, shell fragments or feathers.[18] These materials may help to camouflage the eggs or may provide some level of insulation; they may also help to keep the eggs in place, and prevent them from sinking into muddy or sandy soil if the nest is accidentally flooded.[19] Ostriches, most tinamous, many ducks, most shorebirds, most terns, some falcons, pheasants, quail, partridges, bustards and sandgrouse are among the species that build scrape nests.

Eggs and young in scrape nests, and the adults that brood them, are more exposed to predators and the elements than those in more sheltered nests; they are on the ground and typically in the open, with little to hide them. The eggs of most ground-nesting birds (including those that use scrape nests) are cryptically coloured to help camouflage them when the adult is not covering them; the actual colour generally corresponds to the substrate on which they are laid.[20] Brooding adults also tend to be well camouflaged, and may be difficult to flush from the nest. Most ground-nesting species have well-developed distraction displays, which are used to draw (or drive) potential predators from the area around the nest.[21] Most species with this type of nest have precocial young, which quickly leave the nest upon hatching.[22]

Female peregrine falcon nest-scraping on artificial ledge on Derby Cathedral. Both sexes contribute to the creation of a bare, shallow depression in soil or gravel.

In cool climates (such as in the high Arctic or at high elevations), the depth of a scrape nest can be critical to both the survival of developing eggs and the fitness of the parent bird incubating them. The scrape must be deep enough that eggs are protected from the convective cooling caused by cold winds, but shallow enough that they and the parent bird are not too exposed to the cooling influences of ground temperatures, particularly where the permafrost layer rises to mere centimeters below the nest. Studies have shown that an egg within a scrape nest loses heat 9% more slowly than an egg placed on the ground beside the nest; in such a nest lined with natural vegetation, heat loss is reduced by an additional 25%.[23] The insulating factor of nest lining is apparently so critical to egg survival that some species, including Kentish plovers, will restore experimentally altered levels of insulation to their pre-adjustment levels (adding or subtracting material as necessary) within 24 hours.[24]

 
Other nest linings, like the lichen in this American golden-plover scrape, may provide some level of insulation for the eggs, or may help to camouflage them.

In warm climates, such as deserts and salt flats, heat rather than cold can kill the developing embryos. In such places, scrapes are shallower and tend to be lined with non-vegetative material (including shells, feathers, sticks and soil),[25] which allows convective cooling to occur as air moves over the eggs. Some species, such as the lesser nighthawk and the red-tailed tropicbird, help reduce the nest's temperature by placing it in partial or full shade.[26][27] Others, including some shorebirds, cast shade with their bodies as they stand over their eggs. Some shorebirds also soak their breast feathers with water and then sit on the eggs, providing moisture to enable evaporative cooling.[28] Parent birds keep from overheating themselves by gular panting while they are incubating, frequently exchanging incubation duties, and standing in water when they are not incubating.[29]

The technique used to construct a scrape nest varies slightly depending on the species. Beach-nesting terns, for instance, fashion their nests by rocking their bodies on the sand in the place they have chosen to site their nest,[30] while skimmers build their scrapes with their feet, kicking sand backwards while resting on their bellies and turning slowly in circles.[31] The ostrich also scratches out its scrape with its feet, though it stands while doing so.[32] Many tinamous lay their eggs on a shallow mat of dead leaves they have collected and placed under bushes or between the root buttresses of trees,[33] and kagus lay theirs on a pile of dead leaves against a log, tree trunk or vegetation.[34] Marbled godwits stomp a grassy area flat with their feet, then lay their eggs, while other grass-nesting waders bend vegetation over their nests so as to avoid detection from above.[35] Many female ducks, particularly in the northern latitudes, line their shallow scrape nests with down feathers plucked from their own breasts, as well as with small amounts of vegetation.[36] Among scrape-nesting birds, the three-banded courser and Egyptian plover are unique in their habit of partially burying their eggs in the sand of their scrapes.[37]

Mound edit

 
The huge mound nest of the malleefowl acts like a compost heap, warming and incubating the eggs as it rots around them.

Burying eggs as a form of incubation reaches its zenith with the Australasian megapodes. Several megapode species construct enormous mound nests made of soil, branches, sticks, twigs and leaves, and lay their eggs within the rotting mass. The heat generated by these mounds, which are in effect giant compost heaps, warms and incubates the eggs.[1] The nest heat results from the respiration of thermophilic fungi and other microorganisms.[38] The size of some of these mounds can be truly staggering; several of the largest—which contain more than 100 cubic metres (130 cu yd) of material, and probably weigh more than 50 tons (45,000 kg)[38]—were initially thought to be Aboriginal middens.[39]

In most mound-building species, males do most or all of the nest construction and maintenance. Using his strong legs and feet, the male scrapes together material from the area around his chosen nest site, gradually building a conical or bell-shaped pile. This process can take five to seven hours a day for more than a month. While mounds are typically reused for multiple breeding seasons, new material must be added each year to generate the appropriate amount of heat. A female will begin to lay eggs in the nest only when the mound's temperature has reached an optimal level.[40]

 
The mound nests of flamingos, like these Chilean flamingos, help to protect their eggs from fluctuating water levels.

Both the temperature and the moisture content of the mound are critical to the survival and development of the eggs, so both are carefully regulated for the entire length of the breeding season (which may last for as long as eight months), principally by the male.[38] Ornithologists believe that megapodes may use sensitive areas in their mouths to assess mound temperatures; each day during the breeding season, the male digs a pit into his mound and sticks his head in.[41] If the mound's core temperature is a bit low, he adds fresh moist material to the mound, and stirs it in; if it is too high, he opens the top of the mound to allow some of the excess heat to escape. This regular monitoring also keeps the mound's material from becoming compacted, which would inhibit oxygen diffusion to the eggs and make it more difficult for the chicks to emerge after hatching.[40] The malleefowl, which lives in more open forest than do other megapodes, uses the sun to help warm its nest as well—opening the mound at midday during the cool spring and autumn months to expose the plentiful sand incorporated into the nest to the sun's warming rays, then using that warm sand to insulate the eggs during the cold nights. During hot summer months, the malleefowl opens its nest mound only in the cool early morning hours, allowing excess heat to escape before recovering the mound completely.[42] One recent study showed that the sex ratio of Australian brushturkey hatchlings correlated strongly with mound temperatures; females hatched from eggs incubated at higher mean temperatures.[43]

Flamingos make a different type of mound nest. Using their beaks to pull material towards them,[44] they fashion a cone-shaped pile of mud between 15–46 cm (6–18 in) tall, with a small depression in the top to house their single egg.[45] The height of the nest varies with the substrate upon which it is built; those on clay sites are taller on average than those on dry or sandy sites.[44] The height of the nest and the circular, often water-filled trench which surrounds it (the result of the removal of material for the nest) help to protect the egg from fluctuating water levels and excessive heat at ground level. In East Africa, for example, temperatures at the top of the nest mound average some 20 °C (36 °F) cooler than those of the surrounding ground.[44]

The base of the horned coot's enormous nest is a mound built of stones, gathered one at a time by the pair, using their beaks. These stones, which may weigh as much as 450 g (about a pound) each, are dropped into the shallow water of a lake, making a cone-shaped pile which can measure as much as 4 m2 (43 sq ft) at the bottom and 1 m2 (11 sq ft) at the top, and 0.6 m (2.0 ft) in height. The total combined weight of the mound's stones may approach 1.5 tons (1,400 kg). Once the mound has been completed, a sizable platform of aquatic vegetation is constructed on top. The entire structure is typically reused for many years.[46]

Burrow edit

 
Like most burrow-nesting species, sand martins dig a horizontal tunnel into a vertical dirt cliff.

Soil plays a different role in the burrow nest; here, the eggs and young—and in most cases the incubating parent bird—are sheltered under the earth. Most burrow-nesting birds excavate their own burrows, but some use those excavated by other species and are known as secondary nesters; burrowing owls, for example, sometimes use the burrows of prairie dogs, ground squirrels, badgers or tortoises,[47] China's endemic white-browed tits use the holes of ground-nesting rodents[48] and common kingfishers occasionally nest in rabbit burrows.[49] Burrow nests are particularly common among seabirds at high latitudes, as they provide protection against both cold temperatures and predators.[50] Puffins, shearwaters, some megapodes, motmots, todies, most kingfishers, the crab plover, miners and leaftossers are among the species which use burrow nests.

Most burrow nesting species dig a horizontal tunnel into a vertical (or nearly vertical) dirt cliff, with a chamber at the tunnel's end to house the eggs.[51] The length of the tunnel varies depending on the substrate and the species; sand martins make relatively short tunnels ranging from 50–90 cm (20–35 in),[52] for example, while those of the burrowing parakeet can extend for more than three meters (nearly 10 ft).[53] Some species, including the ground-nesting puffbirds, prefer flat or gently sloping land, digging their entrance tunnels into the ground at an angle.[54] In a more extreme example, the D'Arnaud's barbet digs a vertical tunnel shaft more than a meter (39 in) deep, with its nest chamber excavated off to the side at some height above the shaft's bottom; this arrangement helps to keep the nest from being flooded during heavy rain.[55] Buff-breasted paradise-kingfishers dig their nests into the compacted mud of active termite mounds, either on the ground or in trees.[49] Specific soil types may favour certain species and it is speculated that several species of bee-eater favor loess soils which are easy to penetrate.[56][57]

 
Increased vulnerability to predators may have led some burrow-nesting species, like the European bee-eater, to become colonial breeders.

Birds use a combination of their beaks and feet to excavate burrow nests. The tunnel is started with the beak; the bird either probes at the ground to create a depression, or flies toward its chosen nest site on a cliff wall and hits it with its bill. The latter method is not without its dangers; there are reports of kingfishers being fatally injured in such attempts.[49] Some birds remove tunnel material with their bills, while others use their bodies or shovel the dirt out with one or both feet. Female paradise-kingfishers are known to use their long tails to clear the loose soil.[49]

Some crepuscular petrels and prions are able to identify their own burrows within dense colonies by smell.[58] Sand martins learn the location of their nest within a colony, and will accept any chick put into that nest until right before the young fledge.[59]

Not all burrow-nesting species incubate their young directly. Some megapode species bury their eggs in sandy pits dug where sunlight, subterranean volcanic activity, or decaying tree roots will warm the eggs.[1][38] The crab plover also uses a burrow nest, the warmth of which allows it to leave the eggs unattended for as long as 58 hours.[60]

Predation levels on some burrow-nesting species can be quite high; on Alaska's Wooded Islands, for example, river otters munched their way through some 23 percent of the island's fork-tailed storm-petrel population during a single breeding season in 1977.[61] There is some evidence that increased vulnerability may lead some burrow-nesting species to form colonies, or to nest closer to rival pairs in areas of high predation than they might otherwise do.[62]

Cavity edit

 
"Secondary cavity nesters", like this cobalt-rumped parrotlet, use natural cavities or holes excavated by other species.

The cavity nest is a chamber, typically in living or dead wood, but sometimes in the trunks of tree ferns[63] or large cacti, including saguaro.[63][64] In tropical areas, cavities are sometimes excavated in arboreal insect nests.[65][66] A relatively small number of species, including woodpeckers, trogons, some nuthatches and many barbets, can excavate their own cavities. Far more species—including parrots, tits, bluebirds, most hornbills, some kingfishers, some owls, some ducks and some flycatchers—use natural cavities, or those abandoned by species able to excavate them; they also sometimes usurp cavity nests from their excavating owners. Those species that excavate their own cavities are known as "primary cavity nesters", while those that use natural cavities or those excavated by other species are called "secondary cavity nesters". Both primary and secondary cavity nesters can be enticed to use nest boxes (also known as bird houses); these mimic natural cavities, and can be critical to the survival of species in areas where natural cavities are lacking.[67]

Woodpeckers use their chisel-like bills to excavate their cavity nests, a process which takes, on average, about two weeks.[64] Cavities are normally excavated on the downward-facing side of a branch, presumably to make it more difficult for predators to access the nest, and to reduce the chance that rain floods the nest.[68] There is also some evidence that fungal rot may make the wood on the underside of leaning trunks and branches easier to excavate.[68] Most woodpeckers use a cavity for only a single year. The endangered red-cockaded woodpecker is an exception; it takes far longer—up to two years—to excavate its nest cavity, and may reuse it for more than two decades.[64] The typical woodpecker nest has a short horizontal tunnel which leads to a vertical chamber within the trunk. The size and shape of the chamber depends on species, and the entrance hole is typically only as large as is needed to allow access for the adult birds. While wood chips are removed during the excavation process, most species line the floor of the cavity with a fresh bed of them before laying their eggs.

 
Only a relatively small number of species, including the woodpeckers, are capable of excavating their own cavity nests.

Trogons excavate their nests by chewing cavities into very soft dead wood; some species make completely enclosed chambers (accessed by upward-slanting entrance tunnels), while others—like the extravagantly plumed resplendent quetzal—construct more open niches.[66] In most trogon species, both sexes help with nest construction. The process may take several months, and a single pair may start several excavations before finding a tree or stump with wood of the right consistency.

Species which use natural cavities or old woodpecker nests sometimes line the cavity with soft material such as grass, moss, lichen, feathers or fur. Though a number of studies have attempted to determine whether secondary cavity nesters preferentially choose cavities with entrance holes facing certain directions, the results remain inconclusive.[69] While some species appear to preferentially choose holes with certain orientations, studies (to date) have not shown consistent differences in fledging rates between nests oriented in different directions.[69]

Cavity-dwelling species have to contend with the danger of predators accessing their nest, catching them and their young inside and unable to get out.[70] They have a variety of methods for decreasing the likelihood of this happening. Red-cockaded woodpeckers peel bark around the entrance, and drill wells above and below the hole; since they nest in live trees, the resulting flow of resin forms a barrier that prevents snakes from reaching the nests.[71] Red-breasted nuthatches smear sap around the entrance holes to their nests, while white-breasted nuthatches rub foul-smelling insects around theirs.[72] Eurasian nuthatches wall up part of their entrance holes with mud, decreasing the size and sometimes extending the tunnel part of the chamber. Most female hornbills seal themselves into their cavity nests, using a combination of mud (in some species brought by their mates), food remains and their own droppings to reduce the entrance hole to a narrow slit.[73]

A few birds are known to use the nests of insects within which they create a cavity in which they lay their eggs. These include the rufous woodpecker which nests in the arboreal nests of Crematogaster ants and the collared kingfisher which uses termite nests.[74]

Cup edit

 
Like many small birds, the purple-crowned fairy uses considerable amounts of spider silk in its cup nest.

The cup nest is smoothly hemispherical inside, with a deep depression to house the eggs. Most are made of pliable materials—including grasses—though a small number are made of mud or saliva.[75] Many passerines and a few non-passerines, including some hummingbirds and some swifts, build this type of nest.

 
Cup nest of a common blackbird

Small bird species in more than 20 passerine families, and a few non-passerines—including most hummingbirds, kinglets and crests in the genus Regulus, some tyrant flycatchers and several New World warblers—use considerable amounts of spider silk in the construction of their nests.[76][77] The lightweight material is strong and extremely flexible, allowing the nest to mold to the adult during incubation (reducing heat loss), then to stretch to accommodate the growing nestlings; as it is sticky, it also helps to bind the nest to the branch or leaf to which it is attached.[77]

 
 
Museum specimen of a blue-grey gnatcatcher cup nest, made with lichens, hair, and spiderwebs.

Many swifts and some hummingbirds[78] use thick, quick-drying saliva to anchor their nests. The chimney swift starts by dabbing two globs of saliva onto the wall of a chimney or tree trunk. In flight, it breaks a small twig from a tree and presses it into the saliva, angling the twig downwards so that the central part of the nest is the lowest. It continues adding globs of saliva and twigs until it has made a crescent-shaped cup.[79]

Cup-shaped nest insulation has been found to be related to nest mass,[80][81] nest wall thickness,[81][82][83] nest depth,[80][81] nest weave density/porosity,[80][82][84] surface area,[81] height above ground[80] and elevation above sea level.[84]

A pair of long-tailed tits in the process of building a nest

More recently, nest insulation has been found to be related to the mass of the incubating parent.[81] This is known as an allometric relationship. Nest walls are constructed with an adequate quantity of nesting material so that the nest will be capable of supporting the contents of the nest. Nest thickness, nest mass and nest dimensions therefore correlate with the mass of the adult bird.[81] The flow-on consequence of this is that nest insulation is also related to parent mass.[81]

 
Hanging bird nest

Saucer or plate edit

The saucer or plate nest, though superficially similar to a cup nest, has at most only a shallow depression to house the eggs.

Platform edit

 
Many raptors, like the osprey, use the same huge platform nest for years, adding new material each season.
 
Some waterbirds, including the grebes, build floating platform nests.

The platform nest is a large structure, often many times the size of the (typically large) bird which has built it. Depending on the species, these nests can be on the ground or elevated.[85] In the case of raptor nests, or eyries (also spelled aerie), these are often used for many years, with new material added each breeding season. In some cases, the nests grow large enough to cause structural damage to the tree itself, particularly during bad storms where the weight of the nest can cause additional stress on wind-tossed branches.

Pendent edit

 
Taveta golden weaver building pendent nest.

The pendent nest is an elongated sac woven of pliable materials such as grasses and plant fibers and suspended from a branch. Oropendolas, caciques, orioles, weavers and sunbirds are among the species that weave pendent nests. In weaver birds, this is pendant, suspended from a single point hanging from branch while many other birds incorporate more than one branch to support the nest.

Sphere edit

The sphere nest is a roundish structure; it is completely enclosed, except for a small opening which allows access. Most spherical nests are woven out of plant material. Spider webs are also frequently used, upon which other material such as lichens may be stuck for camouflage. The cape penduline tit incorporates false entrances, the parent bird carefully making sure to close the actual entrance when leaving the nest. The entrances are lined with spider webs which help seal the openings.[86]

Nest protection and sanitation edit

Many species of bird conceal their nests to protect them from predators. Some species may choose nest sites that are inaccessible or build the nest so as to deter predators.[87] Bird nests can also act as habitats for other inquiline species which may not affect the bird directly. Birds have also evolved nest sanitation measures to reduce the effects of parasites and pathogens on nestlings.

Some aquatic species such as grebes are very careful when approaching and leaving the nest so as not to reveal the location. Some species will use leaves to cover up the nest prior to leaving.

Ground birds such as plovers may use broken wing or rodent run displays to distract predators from nests.[88]

Many species attack predators or apparent predators near their nests. Kingbirds attack other birds that come too close. In North America, northern mockingbirds, blue jays, and Arctic terns can peck hard enough to draw blood.[89] In Australia, a bird attacking a person near its nest is said to swoop the person. The Australian magpie is particularly well known for this behavior.[90]

Nests can become home to many other organisms including parasites and pathogens.[91] The excreta of the fledglings also pose a problem. In most passerines, the adults actively dispose the fecal sacs of young at a distance or consume them. This is believed to help prevent ground predators from detecting nests.[92] Young birds of prey however usually void their excreta beyond the rims of their nests.[93] Blowflies of the genus Protocalliphora have specialized to become obligate nest parasites with the maggots feeding on the blood of nestlings.[94]

Some birds have been shown to choose aromatic green plant material for constructing nests that may have insecticidal properties,[95][96] while others may use materials such as carnivore scat to repel smaller predators.[97] Some urban birds, house sparrows and house finches in Mexico, have adopted the use of cigarette butts which contain nicotine and other toxic substances that repel ticks and other ectoparasites.[98][99]

Some birds use pieces of snake slough in their nests.[100] It has been suggested that these may deter some nest predators such as squirrels.[101]

Colonial nesting edit

 
Nesting colony of Montezuma oropendolas
Main article: Bird colony

Though most birds nest individually, some species—including seabirds, penguins, flamingos, many herons, gulls, terns, weaver, some corvids and some sparrows—gather together in sizeable colonies. Birds that nest colonially may benefit from increased protection against predation. They may also be able to better use food supplies, by following more successful foragers to their foraging sites.[102]

Ecological importance edit

In constructing nests, birds act as ecosystem engineers by providing a sheltered microclimate and concentrated food sources for invertebrates.[103] A global checklist lists eighteen invertebrate orders that occur in bird nests.[104]

In human culture edit

 
A human-made nest platform in Poland built as a conservation measure and to prevent storks disrupting electricity supplies through nesting on pylons. Three young white storks are on the top of the nest and two Eurasian tree sparrows are perching on the side of the nest.

Many birds may nest close to human habitations. In addition to nest boxes which are often used to encourage cavity nesting birds (see below), other species have been specially encouraged : for example nesting white storks have been protected and held in reverence in many cultures,[105] and the nesting of peregrine falcons on tall modern or historical buildings has captured popular interest.[106]

Colonial breeders produce guano in and around their nesting sites, which is a valuable fertilizer from the Andean Pacific coast and other areas.

The saliva nest of the edible-nest swiftlet is used to make bird's nest soup,[107] long considered a delicacy in China.[108] Collection of the swiftlet nests is big business: in one year, more than 3.5 million nests were exported from Borneo to China,[109] and the industry was estimated at $1 billion US per year (and increasing) in 2008.[107] While the collection is regulated in some areas (at the Gomantong Caves, for example, where nests can be collected only from February to April or July to September), it is not in others, and the swiftlets are declining in areas where the harvest reaches unsustainable levels.[107]

Some species of birds are considered nuisances when they nest in the proximity of human habitations. Feral pigeons are often unwelcome and sometimes also considered as a health risk.[110]

The Beijing National Stadium, principal venue of the 2008 Summer Olympics, has been nicknamed "The Bird Nest" because of its architectural design, which its designers likened to a bird's woven nest.[111]

In the 19th and early 20th centuries, naturalists often collected bird's eggs and their nests. The practice of egg-collecting or oology is now illegal in many jurisdictions worldwide; the study of bird nests is called caliology.[112]

Artificial bird nests edit

 
Artificial duck nest

Bird nests are also built by humans to help in the conservation of certain birds (such as swallows). Swallow nests are generally built with plaster, wood, terracotta or stucco.[113][114]

Artificial nests, such as nest boxes, are an important conservation tool for many species, however nest box programs rarely compare their effectiveness with individuals not using nest boxes. Red-footed falcons using nest boxes in heavily managed landscapes produced fewer fledglings than those nesting in natural nests, but also than pairs nesting in nest boxes in more natural habitats.[115]

References edit

Notes edit

  1. ^ a b c Campbell & Lack 1985, p. 386
  2. ^ Campbell & Lack 1985, p. 345
  3. ^ Skutch, Alexander F (1960), "The nest as a dormitory", Ibis, 103 (1): 50–70, doi:10.1111/j.1474-919X.1961.tb02420.x.
  4. ^ smithsonianscience.org 2015-04-20 Bird nests: Variety is Key for the world's avian Architects 3 January 2017 at the Wayback Machine
  5. ^ Campbell & Lack 1985, p. 387
  6. ^ Felix, Jiri (1973). Garden and Field Birds. Octopus books. p. 17. ISBN 0-7064-0236-7.
  7. ^ Ehrlich et al. 1994, pp. 228–232
  8. ^ del Hoyo 1992, p. 692
  9. ^ Hogan 2010.
  10. ^ del Hoyo 1992, p. 148
  11. ^ Ehrlich et al. 1994, p. 252
  12. ^ Ehrlich et al. 1994, p. 260
  13. ^ Cohn-Haft 1999, p. 295
  14. ^ Jaramillo 2001, p. 548
  15. ^ Short & Horne 2002b, p. 282
  16. ^ JE, Simon; Pacheco (2005), "On the standardization of nest descriptions of neotropical birds" (PDF), Revista Brasileira de Ornitologia, 13 (2): 143–154, (PDF) from the original on 20 July 2008
  17. ^ Campbell & Lack 1985, p. 390
  18. ^ Ehrlich et al. 1994, p. xxii
  19. ^ Ehrlich et al. 1994, p. 441
  20. ^ Campbell & Lack 1985, p. 174
  21. ^ Campbell & Lack 1985, p. 145
  22. ^ Williams, Ernest Herbert (2005), The Nature Handbook: A Guide to Observing the Great Outdoors, Oxford University Press, US, p. 115, ISBN 978-0-19-517194-5
  23. ^ Reid, J. M.; Cresswell, W.; Holt, S.; Mellanby, R. J.; Whitby, D. P.; Ruxton, G. D (2002), "Nest scrape design and clutch heat loss in the Pectoral Sandpiper (Calidris melanotos)", Functional Ecology, 16 (3): 305–316, doi:10.1046/j.1365-2435.2002.00632.x.
  24. ^ Szentirmai, István; Székely, Tamás (2002), "Do Kentish plovers regulate the amount of their nest material? An Experimental Test", Behaviour, 139 (6): 847–859, doi:10.1163/156853902320262844, JSTOR 4535956.
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Cited texts edit

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External links edit

 
Wikimedia Commons has media related to Bird nests.
 
Wikisource has the text of the 1911 Encyclopædia Britannica article "Nidification".

January 01, 1970
bird, nest, animal, nests, general, nest, other, uses, bird, nest, bird, nest, spot, which, bird, lays, incubates, eggs, raises, young, although, term, popularly, refers, specific, structure, made, bird, itself, such, grassy, nest, american, robin, eurasian, b. For animal nests in general see Nest For other uses see Bird s nest A bird nest is the spot in which a bird lays and incubates its eggs and raises its young Although the term popularly refers to a specific structure made by the bird itself such as the grassy cup nest of the American robin or Eurasian blackbird or the elaborately woven hanging nest of the Montezuma oropendola or the village weaver that is too restrictive a definition For some species a nest is simply a shallow depression made in sand for others it is the knot hole left by a broken branch a burrow dug into the ground a chamber drilled into a tree an enormous rotting pile of vegetation and earth a shelf made of dried saliva or a mud dome with an entrance tunnel The smallest bird nests are those of some hummingbirds tiny cups which can be a mere 2 cm 0 8 in across and 2 3 cm 0 8 1 2 in high 1 At the other extreme some nest mounds built by the dusky scrubfowl measure more than 11 m 36 ft in diameter and stand nearly 5 m 16 ft tall 2 The study of birds nests is known as caliology Deep cup nest of the great reed warbler Not all bird species build nests Some species lay their eggs directly on the ground or rocky ledges while brood parasites lay theirs in the nests of other birds letting unwitting foster parents do the work of rearing the young Although nests are primarily used for breeding they may also be reused in the non breeding season for roosting and some species build special dormitory nests or roost nests or winter nest that are used only for roosting 3 Most birds build a new nest each year though some refurbish their old nests 4 The large eyries or aeries of some eagles are platform nests that have been used and refurbished for several years In the majority of nest building species the female does most or all of the nest construction in others both partners contribute sometimes the male builds the nest and the hen lines it 5 6 In some polygynous species however the male does most or all of the nest building The nest may also form a part of the courtship display such as in weaver birds The ability to choose and maintain good nest sites and build high quality nests may be selected for by females in these species In some species the young from previous broods may also act as helpers for the adults Contents 1 Type 1 1 Scrape 1 2 Mound 1 3 Burrow 1 4 Cavity 1 5 Cup 1 6 Saucer or plate 1 7 Platform 1 8 Pendent 1 9 Sphere 2 Nest protection and sanitation 3 Colonial nesting 4 Ecological importance 5 In human culture 6 Artificial bird nests 7 References 7 1 Notes 7 2 Cited texts 8 External linksType edit nbsp Not every bird species builds or uses a nest Some auks for instance including common murre thick billed murre and razorbill lay their eggs directly onto the narrow rocky ledges they use as breeding sites 7 The eggs of these species are dramatically pointed at one end so that they roll in a circle when disturbed This is critical for the survival of the developing eggs as there are no nests to keep them from rolling off the side of the cliff Presumably because of the vulnerability of their unprotected eggs parent birds of these auk species rarely leave them unattended 8 Nest location and architecture is strongly influenced by local topography and other abiotic factors 9 King penguins and emperor penguins also do not build nests instead they tuck their eggs and chicks between their feet and folds of skin on their lower bellies They are thus able to move about while incubating though in practice only the emperor penguin regularly does so Emperor penguins breed during the harshest months of the Antarctic winter and their mobility allows them to form huge huddled masses which help them to withstand the extremely high winds and low temperatures of the season Without the ability to share body heat temperatures in the centre of tight groups can be as much as 10C above the ambient air temperature the penguins would expend far more energy trying to stay warm and breeding attempts would probably fail 10 Some crevice nesting species including ashy storm petrel pigeon guillemot Eurasian eagle owl and Hume s tawny owl lay their eggs in the relative shelter of a crevice in the rocks or a gap between boulders but provide no additional nest material 11 12 Potoos lay their single egg directly atop a broken stump or into a shallow depression on a branch typically where an upward pointing branch died and fell off leaving a small scar or knot hole 13 Brood parasites such as the New World cowbirds the honeyguides and many of the Old World and Australasian cuckoos lay their eggs in the active nests of other species 14 15 16 Scrape edit nbsp Some nest linings such as the shell fragments in this Charadrius plover scrape may help to prevent the eggs from sinking into muddy or sandy soil The simplest nest construction is the scrape which is merely a shallow depression in soil or vegetation 17 This nest type which typically has a rim deep enough to keep the eggs from rolling away is sometimes lined with bits of vegetation small stones shell fragments or feathers 18 These materials may help to camouflage the eggs or may provide some level of insulation they may also help to keep the eggs in place and prevent them from sinking into muddy or sandy soil if the nest is accidentally flooded 19 Ostriches most tinamous many ducks most shorebirds most terns some falcons pheasants quail partridges bustards and sandgrouse are among the species that build scrape nests Eggs and young in scrape nests and the adults that brood them are more exposed to predators and the elements than those in more sheltered nests they are on the ground and typically in the open with little to hide them The eggs of most ground nesting birds including those that use scrape nests are cryptically coloured to help camouflage them when the adult is not covering them the actual colour generally corresponds to the substrate on which they are laid 20 Brooding adults also tend to be well camouflaged and may be difficult to flush from the nest Most ground nesting species have well developed distraction displays which are used to draw or drive potential predators from the area around the nest 21 Most species with this type of nest have precocial young which quickly leave the nest upon hatching 22 source source source source source source Female peregrine falcon nest scraping on artificial ledge on Derby Cathedral Both sexes contribute to the creation of a bare shallow depression in soil or gravel In cool climates such as in the high Arctic or at high elevations the depth of a scrape nest can be critical to both the survival of developing eggs and the fitness of the parent bird incubating them The scrape must be deep enough that eggs are protected from the convective cooling caused by cold winds but shallow enough that they and the parent bird are not too exposed to the cooling influences of ground temperatures particularly where the permafrost layer rises to mere centimeters below the nest Studies have shown that an egg within a scrape nest loses heat 9 more slowly than an egg placed on the ground beside the nest in such a nest lined with natural vegetation heat loss is reduced by an additional 25 23 The insulating factor of nest lining is apparently so critical to egg survival that some species including Kentish plovers will restore experimentally altered levels of insulation to their pre adjustment levels adding or subtracting material as necessary within 24 hours 24 nbsp Other nest linings like the lichen in this American golden plover scrape may provide some level of insulation for the eggs or may help to camouflage them In warm climates such as deserts and salt flats heat rather than cold can kill the developing embryos In such places scrapes are shallower and tend to be lined with non vegetative material including shells feathers sticks and soil 25 which allows convective cooling to occur as air moves over the eggs Some species such as the lesser nighthawk and the red tailed tropicbird help reduce the nest s temperature by placing it in partial or full shade 26 27 Others including some shorebirds cast shade with their bodies as they stand over their eggs Some shorebirds also soak their breast feathers with water and then sit on the eggs providing moisture to enable evaporative cooling 28 Parent birds keep from overheating themselves by gular panting while they are incubating frequently exchanging incubation duties and standing in water when they are not incubating 29 The technique used to construct a scrape nest varies slightly depending on the species Beach nesting terns for instance fashion their nests by rocking their bodies on the sand in the place they have chosen to site their nest 30 while skimmers build their scrapes with their feet kicking sand backwards while resting on their bellies and turning slowly in circles 31 The ostrich also scratches out its scrape with its feet though it stands while doing so 32 Many tinamous lay their eggs on a shallow mat of dead leaves they have collected and placed under bushes or between the root buttresses of trees 33 and kagus lay theirs on a pile of dead leaves against a log tree trunk or vegetation 34 Marbled godwits stomp a grassy area flat with their feet then lay their eggs while other grass nesting waders bend vegetation over their nests so as to avoid detection from above 35 Many female ducks particularly in the northern latitudes line their shallow scrape nests with down feathers plucked from their own breasts as well as with small amounts of vegetation 36 Among scrape nesting birds the three banded courser and Egyptian plover are unique in their habit of partially burying their eggs in the sand of their scrapes 37 Mound edit nbsp The huge mound nest of the malleefowl acts like a compost heap warming and incubating the eggs as it rots around them Burying eggs as a form of incubation reaches its zenith with the Australasian megapodes Several megapode species construct enormous mound nests made of soil branches sticks twigs and leaves and lay their eggs within the rotting mass The heat generated by these mounds which are in effect giant compost heaps warms and incubates the eggs 1 The nest heat results from the respiration of thermophilic fungi and other microorganisms 38 The size of some of these mounds can be truly staggering several of the largest which contain more than 100 cubic metres 130 cu yd of material and probably weigh more than 50 tons 45 000 kg 38 were initially thought to be Aboriginal middens 39 In most mound building species males do most or all of the nest construction and maintenance Using his strong legs and feet the male scrapes together material from the area around his chosen nest site gradually building a conical or bell shaped pile This process can take five to seven hours a day for more than a month While mounds are typically reused for multiple breeding seasons new material must be added each year to generate the appropriate amount of heat A female will begin to lay eggs in the nest only when the mound s temperature has reached an optimal level 40 nbsp The mound nests of flamingos like these Chilean flamingos help to protect their eggs from fluctuating water levels Both the temperature and the moisture content of the mound are critical to the survival and development of the eggs so both are carefully regulated for the entire length of the breeding season which may last for as long as eight months principally by the male 38 Ornithologists believe that megapodes may use sensitive areas in their mouths to assess mound temperatures each day during the breeding season the male digs a pit into his mound and sticks his head in 41 If the mound s core temperature is a bit low he adds fresh moist material to the mound and stirs it in if it is too high he opens the top of the mound to allow some of the excess heat to escape This regular monitoring also keeps the mound s material from becoming compacted which would inhibit oxygen diffusion to the eggs and make it more difficult for the chicks to emerge after hatching 40 The malleefowl which lives in more open forest than do other megapodes uses the sun to help warm its nest as well opening the mound at midday during the cool spring and autumn months to expose the plentiful sand incorporated into the nest to the sun s warming rays then using that warm sand to insulate the eggs during the cold nights During hot summer months the malleefowl opens its nest mound only in the cool early morning hours allowing excess heat to escape before recovering the mound completely 42 One recent study showed that the sex ratio of Australian brushturkey hatchlings correlated strongly with mound temperatures females hatched from eggs incubated at higher mean temperatures 43 Flamingos make a different type of mound nest Using their beaks to pull material towards them 44 they fashion a cone shaped pile of mud between 15 46 cm 6 18 in tall with a small depression in the top to house their single egg 45 The height of the nest varies with the substrate upon which it is built those on clay sites are taller on average than those on dry or sandy sites 44 The height of the nest and the circular often water filled trench which surrounds it the result of the removal of material for the nest help to protect the egg from fluctuating water levels and excessive heat at ground level In East Africa for example temperatures at the top of the nest mound average some 20 C 36 F cooler than those of the surrounding ground 44 The base of the horned coot s enormous nest is a mound built of stones gathered one at a time by the pair using their beaks These stones which may weigh as much as 450 g about a pound each are dropped into the shallow water of a lake making a cone shaped pile which can measure as much as 4 m2 43 sq ft at the bottom and 1 m2 11 sq ft at the top and 0 6 m 2 0 ft in height The total combined weight of the mound s stones may approach 1 5 tons 1 400 kg Once the mound has been completed a sizable platform of aquatic vegetation is constructed on top The entire structure is typically reused for many years 46 Burrow edit nbsp Like most burrow nesting species sand martins dig a horizontal tunnel into a vertical dirt cliff Soil plays a different role in the burrow nest here the eggs and young and in most cases the incubating parent bird are sheltered under the earth Most burrow nesting birds excavate their own burrows but some use those excavated by other species and are known as secondary nesters burrowing owls for example sometimes use the burrows of prairie dogs ground squirrels badgers or tortoises 47 China s endemic white browed tits use the holes of ground nesting rodents 48 and common kingfishers occasionally nest in rabbit burrows 49 Burrow nests are particularly common among seabirds at high latitudes as they provide protection against both cold temperatures and predators 50 Puffins shearwaters some megapodes motmots todies most kingfishers the crab plover miners and leaftossers are among the species which use burrow nests Most burrow nesting species dig a horizontal tunnel into a vertical or nearly vertical dirt cliff with a chamber at the tunnel s end to house the eggs 51 The length of the tunnel varies depending on the substrate and the species sand martins make relatively short tunnels ranging from 50 90 cm 20 35 in 52 for example while those of the burrowing parakeet can extend for more than three meters nearly 10 ft 53 Some species including the ground nesting puffbirds prefer flat or gently sloping land digging their entrance tunnels into the ground at an angle 54 In a more extreme example the D Arnaud s barbet digs a vertical tunnel shaft more than a meter 39 in deep with its nest chamber excavated off to the side at some height above the shaft s bottom this arrangement helps to keep the nest from being flooded during heavy rain 55 Buff breasted paradise kingfishers dig their nests into the compacted mud of active termite mounds either on the ground or in trees 49 Specific soil types may favour certain species and it is speculated that several species of bee eater favor loess soils which are easy to penetrate 56 57 nbsp Increased vulnerability to predators may have led some burrow nesting species like the European bee eater to become colonial breeders Birds use a combination of their beaks and feet to excavate burrow nests The tunnel is started with the beak the bird either probes at the ground to create a depression or flies toward its chosen nest site on a cliff wall and hits it with its bill The latter method is not without its dangers there are reports of kingfishers being fatally injured in such attempts 49 Some birds remove tunnel material with their bills while others use their bodies or shovel the dirt out with one or both feet Female paradise kingfishers are known to use their long tails to clear the loose soil 49 Some crepuscular petrels and prions are able to identify their own burrows within dense colonies by smell 58 Sand martins learn the location of their nest within a colony and will accept any chick put into that nest until right before the young fledge 59 Not all burrow nesting species incubate their young directly Some megapode species bury their eggs in sandy pits dug where sunlight subterranean volcanic activity or decaying tree roots will warm the eggs 1 38 The crab plover also uses a burrow nest the warmth of which allows it to leave the eggs unattended for as long as 58 hours 60 Predation levels on some burrow nesting species can be quite high on Alaska s Wooded Islands for example river otters munched their way through some 23 percent of the island s fork tailed storm petrel population during a single breeding season in 1977 61 There is some evidence that increased vulnerability may lead some burrow nesting species to form colonies or to nest closer to rival pairs in areas of high predation than they might otherwise do 62 Cavity edit nbsp Secondary cavity nesters like this cobalt rumped parrotlet use natural cavities or holes excavated by other species The cavity nest is a chamber typically in living or dead wood but sometimes in the trunks of tree ferns 63 or large cacti including saguaro 63 64 In tropical areas cavities are sometimes excavated in arboreal insect nests 65 66 A relatively small number of species including woodpeckers trogons some nuthatches and many barbets can excavate their own cavities Far more species including parrots tits bluebirds most hornbills some kingfishers some owls some ducks and some flycatchers use natural cavities or those abandoned by species able to excavate them they also sometimes usurp cavity nests from their excavating owners Those species that excavate their own cavities are known as primary cavity nesters while those that use natural cavities or those excavated by other species are called secondary cavity nesters Both primary and secondary cavity nesters can be enticed to use nest boxes also known as bird houses these mimic natural cavities and can be critical to the survival of species in areas where natural cavities are lacking 67 Woodpeckers use their chisel like bills to excavate their cavity nests a process which takes on average about two weeks 64 Cavities are normally excavated on the downward facing side of a branch presumably to make it more difficult for predators to access the nest and to reduce the chance that rain floods the nest 68 There is also some evidence that fungal rot may make the wood on the underside of leaning trunks and branches easier to excavate 68 Most woodpeckers use a cavity for only a single year The endangered red cockaded woodpecker is an exception it takes far longer up to two years to excavate its nest cavity and may reuse it for more than two decades 64 The typical woodpecker nest has a short horizontal tunnel which leads to a vertical chamber within the trunk The size and shape of the chamber depends on species and the entrance hole is typically only as large as is needed to allow access for the adult birds While wood chips are removed during the excavation process most species line the floor of the cavity with a fresh bed of them before laying their eggs nbsp Only a relatively small number of species including the woodpeckers are capable of excavating their own cavity nests Trogons excavate their nests by chewing cavities into very soft dead wood some species make completely enclosed chambers accessed by upward slanting entrance tunnels while others like the extravagantly plumed resplendent quetzal construct more open niches 66 In most trogon species both sexes help with nest construction The process may take several months and a single pair may start several excavations before finding a tree or stump with wood of the right consistency Species which use natural cavities or old woodpecker nests sometimes line the cavity with soft material such as grass moss lichen feathers or fur Though a number of studies have attempted to determine whether secondary cavity nesters preferentially choose cavities with entrance holes facing certain directions the results remain inconclusive 69 While some species appear to preferentially choose holes with certain orientations studies to date have not shown consistent differences in fledging rates between nests oriented in different directions 69 Cavity dwelling species have to contend with the danger of predators accessing their nest catching them and their young inside and unable to get out 70 They have a variety of methods for decreasing the likelihood of this happening Red cockaded woodpeckers peel bark around the entrance and drill wells above and below the hole since they nest in live trees the resulting flow of resin forms a barrier that prevents snakes from reaching the nests 71 Red breasted nuthatches smear sap around the entrance holes to their nests while white breasted nuthatches rub foul smelling insects around theirs 72 Eurasian nuthatches wall up part of their entrance holes with mud decreasing the size and sometimes extending the tunnel part of the chamber Most female hornbills seal themselves into their cavity nests using a combination of mud in some species brought by their mates food remains and their own droppings to reduce the entrance hole to a narrow slit 73 A few birds are known to use the nests of insects within which they create a cavity in which they lay their eggs These include the rufous woodpecker which nests in the arboreal nests of Crematogaster ants and the collared kingfisher which uses termite nests 74 Cup edit nbsp Like many small birds the purple crowned fairy uses considerable amounts of spider silk in its cup nest The cup nest is smoothly hemispherical inside with a deep depression to house the eggs Most are made of pliable materials including grasses though a small number are made of mud or saliva 75 Many passerines and a few non passerines including some hummingbirds and some swifts build this type of nest nbsp Cup nest of a common blackbird Small bird species in more than 20 passerine families and a few non passerines including most hummingbirds kinglets and crests in the genus Regulus some tyrant flycatchers and several New World warblers use considerable amounts of spider silk in the construction of their nests 76 77 The lightweight material is strong and extremely flexible allowing the nest to mold to the adult during incubation reducing heat loss then to stretch to accommodate the growing nestlings as it is sticky it also helps to bind the nest to the branch or leaf to which it is attached 77 nbsp nbsp Museum specimen of a blue grey gnatcatcher cup nest made with lichens hair and spiderwebs Many swifts and some hummingbirds 78 use thick quick drying saliva to anchor their nests The chimney swift starts by dabbing two globs of saliva onto the wall of a chimney or tree trunk In flight it breaks a small twig from a tree and presses it into the saliva angling the twig downwards so that the central part of the nest is the lowest It continues adding globs of saliva and twigs until it has made a crescent shaped cup 79 Cup shaped nest insulation has been found to be related to nest mass 80 81 nest wall thickness 81 82 83 nest depth 80 81 nest weave density porosity 80 82 84 surface area 81 height above ground 80 and elevation above sea level 84 source source source source source source source source A pair of long tailed tits in the process of building a nest More recently nest insulation has been found to be related to the mass of the incubating parent 81 This is known as an allometric relationship Nest walls are constructed with an adequate quantity of nesting material so that the nest will be capable of supporting the contents of the nest Nest thickness nest mass and nest dimensions therefore correlate with the mass of the adult bird 81 The flow on consequence of this is that nest insulation is also related to parent mass 81 nbsp Hanging bird nest Saucer or plate edit The saucer or plate nest though superficially similar to a cup nest has at most only a shallow depression to house the eggs Platform edit nbsp Many raptors like the osprey use the same huge platform nest for years adding new material each season nbsp Some waterbirds including the grebes build floating platform nests The platform nest is a large structure often many times the size of the typically large bird which has built it Depending on the species these nests can be on the ground or elevated 85 In the case of raptor nests or eyries also spelled aerie these are often used for many years with new material added each breeding season In some cases the nests grow large enough to cause structural damage to the tree itself particularly during bad storms where the weight of the nest can cause additional stress on wind tossed branches Pendent edit nbsp Taveta golden weaver building pendent nest The pendent nest is an elongated sac woven of pliable materials such as grasses and plant fibers and suspended from a branch Oropendolas caciques orioles weavers and sunbirds are among the species that weave pendent nests In weaver birds this is pendant suspended from a single point hanging from branch while many other birds incorporate more than one branch to support the nest Sphere edit The sphere nest is a roundish structure it is completely enclosed except for a small opening which allows access Most spherical nests are woven out of plant material Spider webs are also frequently used upon which other material such as lichens may be stuck for camouflage The cape penduline tit incorporates false entrances the parent bird carefully making sure to close the actual entrance when leaving the nest The entrances are lined with spider webs which help seal the openings 86 Nest protection and sanitation editMany species of bird conceal their nests to protect them from predators Some species may choose nest sites that are inaccessible or build the nest so as to deter predators 87 Bird nests can also act as habitats for other inquiline species which may not affect the bird directly Birds have also evolved nest sanitation measures to reduce the effects of parasites and pathogens on nestlings Some aquatic species such as grebes are very careful when approaching and leaving the nest so as not to reveal the location Some species will use leaves to cover up the nest prior to leaving Ground birds such as plovers may use broken wing or rodent run displays to distract predators from nests 88 Many species attack predators or apparent predators near their nests Kingbirds attack other birds that come too close In North America northern mockingbirds blue jays and Arctic terns can peck hard enough to draw blood 89 In Australia a bird attacking a person near its nest is said to swoop the person The Australian magpie is particularly well known for this behavior 90 Nests can become home to many other organisms including parasites and pathogens 91 The excreta of the fledglings also pose a problem In most passerines the adults actively dispose the fecal sacs of young at a distance or consume them This is believed to help prevent ground predators from detecting nests 92 Young birds of prey however usually void their excreta beyond the rims of their nests 93 Blowflies of the genus Protocalliphora have specialized to become obligate nest parasites with the maggots feeding on the blood of nestlings 94 Some birds have been shown to choose aromatic green plant material for constructing nests that may have insecticidal properties 95 96 while others may use materials such as carnivore scat to repel smaller predators 97 Some urban birds house sparrows and house finches in Mexico have adopted the use of cigarette butts which contain nicotine and other toxic substances that repel ticks and other ectoparasites 98 99 Some birds use pieces of snake slough in their nests 100 It has been suggested that these may deter some nest predators such as squirrels 101 Colonial nesting edit nbsp Nesting colony of Montezuma oropendolasMain article Bird colony Though most birds nest individually some species including seabirds penguins flamingos many herons gulls terns weaver some corvids and some sparrows gather together in sizeable colonies Birds that nest colonially may benefit from increased protection against predation They may also be able to better use food supplies by following more successful foragers to their foraging sites 102 Ecological importance editIn constructing nests birds act as ecosystem engineers by providing a sheltered microclimate and concentrated food sources for invertebrates 103 A global checklist lists eighteen invertebrate orders that occur in bird nests 104 In human culture edit nbsp A human made nest platform in Poland built as a conservation measure and to prevent storks disrupting electricity supplies through nesting on pylons Three young white storks are on the top of the nest and two Eurasian tree sparrows are perching on the side of the nest Many birds may nest close to human habitations In addition to nest boxes which are often used to encourage cavity nesting birds see below other species have been specially encouraged for example nesting white storks have been protected and held in reverence in many cultures 105 and the nesting of peregrine falcons on tall modern or historical buildings has captured popular interest 106 Colonial breeders produce guano in and around their nesting sites which is a valuable fertilizer from the Andean Pacific coast and other areas The saliva nest of the edible nest swiftlet is used to make bird s nest soup 107 long considered a delicacy in China 108 Collection of the swiftlet nests is big business in one year more than 3 5 million nests were exported from Borneo to China 109 and the industry was estimated at 1 billion US per year and increasing in 2008 107 While the collection is regulated in some areas at the Gomantong Caves for example where nests can be collected only from February to April or July to September it is not in others and the swiftlets are declining in areas where the harvest reaches unsustainable levels 107 Some species of birds are considered nuisances when they nest in the proximity of human habitations Feral pigeons are often unwelcome and sometimes also considered as a health risk 110 The Beijing National Stadium principal venue of the 2008 Summer Olympics has been nicknamed The Bird Nest because of its architectural design which its designers likened to a bird s woven nest 111 In the 19th and early 20th centuries naturalists often collected bird s eggs and their nests The practice of egg collecting or oology is now illegal in many jurisdictions worldwide the study of bird nests is called caliology 112 Artificial bird nests edit nbsp Artificial duck nest Bird nests are also built by humans to help in the conservation of certain birds such as swallows Swallow nests are generally built with plaster wood terracotta or stucco 113 114 Artificial nests such as nest boxes are an important conservation tool for many species however nest box programs rarely compare their effectiveness with individuals not using nest boxes Red footed falcons using nest boxes in heavily managed landscapes produced fewer fledglings than those nesting in natural nests but also than pairs nesting in nest boxes in more natural habitats 115 References editNotes edit a b c Campbell amp Lack 1985 p 386 Campbell amp Lack 1985 p 345 Skutch Alexander F 1960 The nest as a dormitory Ibis 103 1 50 70 doi 10 1111 j 1474 919X 1961 tb02420 x smithsonianscience org 2015 04 20 Bird nests Variety is Key for the world s avian Architects Archived 3 January 2017 at the Wayback Machine Campbell amp Lack 1985 p 387 Felix Jiri 1973 Garden and Field Birds Octopus books p 17 ISBN 0 7064 0236 7 Ehrlich et al 1994 pp 228 232 del Hoyo 1992 p 692 Hogan 2010 del Hoyo 1992 p 148 Ehrlich et al 1994 p 252 Ehrlich et al 1994 p 260 Cohn Haft 1999 p 295 Jaramillo 2001 p 548 Short amp Horne 2002b p 282 JE Simon Pacheco 2005 On the standardization of nest descriptions of neotropical birds PDF Revista Brasileira de Ornitologia 13 2 143 154 archived PDF from the original on 20 July 2008 Campbell amp Lack 1985 p 390 Ehrlich et al 1994 p xxii Ehrlich et al 1994 p 441 Campbell amp Lack 1985 p 174 Campbell amp Lack 1985 p 145 Williams Ernest Herbert 2005 The Nature Handbook A Guide to Observing the Great Outdoors Oxford University Press US p 115 ISBN 978 0 19 517194 5 Reid J M Cresswell W Holt S Mellanby R J Whitby D P Ruxton G D 2002 Nest scrape design and clutch heat loss in the Pectoral Sandpiper Calidris melanotos Functional Ecology 16 3 305 316 doi 10 1046 j 1365 2435 2002 00632 x Szentirmai Istvan Szekely Tamas 2002 Do Kentish plovers regulate the amount of their nest material An Experimental Test Behaviour 139 6 847 859 doi 10 1163 156853902320262844 JSTOR 4535956 Grant 1982 p 11 Grant 1982 p 60 Howell Thomas R Bartholomew George A 1962 Temperature Regulation in the Red tailed Tropicbird and the Red footed Booby The Condor 64 1 6 18 doi 10 2307 1365438 JSTOR 1365438 Grant 1982 p 61 Grant 1982 p 62 del Hoyo Elliott amp Sargatal 1996 p 637 del Hoyo Elliott amp Sargatal 1996 p 673 del Hoyo 1992 p 80 del Hoyo 1992 p 119 del Hoyo Elliott amp Sargatal 1996 p 222 del Hoyo Elliott amp Sargatal 1996 p 473 del Hoyo 1992 p 558 del Hoyo Elliott amp Sargatal 1996 p 371 a b c d Elliott 1994 p 287 Hansell 2000 p 9 a b Elliott 1994 p 288 Elliott 1994 p 280 Elliott 1994 p 289 Goth Anne 2007 Incubation temperatures and sex ratios in Australian brush turkey Alectura lathami mounds Austral Ecology 32 4 278 285 Bibcode 2007AusEc 32 378G doi 10 1111 j 1442 9993 2007 01709 x a b c del Hoyo 1992 p 516 Seng 2001 p 188 Taylor Barry van Perlo Ber 1998 Rails Sussex Pica Press p 557 ISBN 978 1 873403 59 4 Behrstock 2001 p 344 Harrap amp Quinn 1996 p 21 a b c d Woodall 2001 p 169 Davenport John 1992 Animal Life 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Tina Winter 2005 Nest Boxes More than Just Birdhouses BirdScope 19 1 archived from the original on 19 July 2007 a b Conner 1975 p 373 a b Rendell Wallace B Robertson Raleigh J 1994 Cavity Entry Orientation and Nest site Use by Secondary Hole nesting Birds PDF Journal of Field Ornithology 65 1 27 35 archived PDF from the original on 4 March 2016 Perrins Christopher M Attenborough David Arlott Norman 1987 New Generation Guide to the Birds of Britain and Europe Austin TX University of Texas Press p 230 ISBN 978 0 292 75532 1 Rudolph Kyle amp Conner 1990 Reed 2001 p 437 Kemp 2001 p 469 Moreau R E 1936 XXVI Bird Insect Nesting Associations Ibis 78 3 460 471 doi 10 1111 j 1474 919X 1936 tb03399 x Hansell 2000 p 280 Ehrlich et al 1994 p 445 a b Erickson Laura Spring 2008 The Wonders of Spider Silk BirdScope 22 2 7 Gould amp Gould 2007 p 200 Gould amp Gould 2007 p 196 a b c d Kern M 1984 Racial differences in nests of white crowned sparrows Condor 86 4 455 466 doi 10 2307 1366826 JSTOR 1366826 a b c d e f g Heenan Caragh Seymour R 2011 Structural support not insulation is the primary driver for avian cup shaped nest design Proceedings of the Royal Society B 278 1720 2924 2929 doi 10 1098 rspb 2010 2798 PMC 3151712 PMID 21325330 a b Skowron C Kern M 1980 The insulation in nests of selected North American songbirds Auk 97 4 816 824 doi 10 1093 auk 97 4 816 Whittow F N Berger A J 1977 Heat loss from the nest of the Hawaiian honeycreeper Amakihi Wilson Bulletin 89 480 483 a b Kern M D Van Riper C 1984 Altitudinal variations in nests of the Hawaiian honeycreeper Hemignathus virens virens Condor 86 4 443 454 doi 10 2307 1366825 JSTOR 1366825 Hyde Kenneth 2004 Zoology An Inside View of Animals Dubuque IA Kendall Hunt p 474 ISBN 978 0 7575 0997 1 Skead C J 1959 A study of the Cape penduline tit Anthoscopus minutus minutus Shaw amp Nodder Ostrich 30 sup1 274 288 Bibcode 1959Ostri 30S 274S doi 10 1080 00306525 1959 9633335 ISSN 0030 6525 Rudolph Kyle amp Conner 1990 Byrktedal 1989 Gill 1995 Kaplan 2004 Hicks Ellis A 1959 Checklist and bibliography on the occurrence of insects in birds nests Iowa State College Press Ames Petit Petit amp Petit 1989 Rosenfeld Rosenfeld amp Gratson 1982 Sabrosky Bennett amp Whitworth 1989 Wimberger 1984 Clark amp Mason 1985 Schuetz 2005 Suarez Rodriguez Monserrat Garcia Constantino Macias 2017 An experimental demonstration that house finches add cigarette butts in response to ectoparasites Journal of Avian Biology 48 10 1316 1321 doi 10 1111 jav 01324 ISSN 0908 8857 Suarez Rodriguez M Lopez Rull I MacIas Garcia C 2012 Incorporation of cigarette butts into nests reduces nest ectoparasite load in urban birds New ingredients for an old recipe Biology Letters 9 1 20120931 doi 10 1098 rsbl 2012 0931 PMC 3565511 PMID 23221874 Strecker John K 1926 On the use by birds of snakes sloughs as nesting material PDF Auk 53 4 501 507 doi 10 2307 4075138 JSTOR 4075138 archived PDF from the original on 24 December 2013 Medlin Elizabeth C Risch Thomas S 2006 An experimental test of snake skin use to deter nest predation The Condor 108 4 963 965 doi 10 1650 0010 5422 2006 108 963 AETOSS 2 0 CO 2 S2CID 86039366 Ward amp Zahavi 1973 Boyes Douglas H Lewis Owen T 27 August 2018 Ecology of Lepidoptera associated with bird nests in mid Wales UK Ecological Entomology 44 1 1 10 doi 10 1111 een 12669 ISSN 0307 6946 S2CID 91557693 Berner Lewis Hicks Ellis A June 1959 Checklist and Bibliography on the Occurrence of Insects in Birds Nests The Florida Entomologist 42 2 92 doi 10 2307 3492142 ISSN 0015 4040 JSTOR 3492142 Kushlan James A 1997 The Conservation of Wading Birds Colonial Waterbirds 20 1 129 137 doi 10 2307 1521775 JSTOR 1521775 Cade amp Bird 1990 a b c Couzens Dominic 2008 Top 100 Birding Sites of the World Berkeley CA University of California Press pp 85 86 ISBN 978 0 520 25932 4 Deutsch Jonathan Murakhver Natalya 2012 They Eat That A Cultural Encyclopedia of Weird and Exotic Food from Around the World Santa Barbara CA ABC CLIO p 17 ISBN 978 0 313 38058 7 archived from the original on 4 June 2013 Khanna D R Yadav P R 2005 Biology of Birds New Delhi India Discovery Publishing House p 129 ISBN 978 81 7141 933 3 archived from the original on 3 June 2013 Haag Wackernagel amp Moch 2004 Competition entries for design of Beijing National Stadium Beijing Municipal Commission of Urban Planning Archived from the original on 20 February 2008 Retrieved 25 February 2008 Dixon Charles 1902 Birds nests New York Frederick A Stokes p v Artificial swallow nests Archived 17 March 2014 at the Wayback Machine Terracotta nests Archived 17 March 2014 at the Wayback Machine Bragin E A Bragin A E Katzner T E 2017 Demographic consequences of nestbox use for Red footed Falcons Falco vespertinus in Central Asia Ibis 159 4 841 853 doi 10 1111 ibi 12503 Cited texts edit Behrstock Robert A 2001 Typical Owls in Elphick Chris Dunning John B Jr Sibley David eds The Sibley Guide to Bird Life amp Behaviour London Christopher Helm ISBN 978 0 7136 6250 4 Byrktedal Ingvar 1989 Nest defense behavior of Lesser Golden Plovers PDF Wilson Bull 101 4 579 590 Cade T J Bird D M 1990 Peregrine Falcons Falco peregrinus nesting in an urban environment a review Can Field Nat 104 2 209 218 doi 10 5962 p 356349 Campbell Bruce Lack Elizabeth eds 1985 A Dictionary of Birds Carlton England T and A D Poyser ISBN 978 0 85661 039 4 Clark L Mason J Russell 1985 Use of nest material as insecticidal and anti pathogenic agents by the European Starling Oecologia 67 2 169 176 Bibcode 1985Oecol 67 169C doi 10 1007 BF00384280 PMID 28311305 S2CID 32307579 Cohn Haft Mario 1999 Family Nyctibiidae Potoos in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 5 Barn owls to Hummingbirds Barcelona Lynx Edicions ISBN 978 84 87334 25 2 Collar N J 2001 Family Trogonidae Trogons in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 6 Mousebirds to Hornbills Barcelona Lynx Edicions ISBN 978 84 87334 30 6 Collias Nicholas E 1997 On the origin and evolution of nest building by passerine birds PDF Condor 99 2 253 270 doi 10 2307 1369932 JSTOR 1369932 Conner Richard N 1975 Orientation of entrances to woodpecker nest cavities Auk 92 2 371 374 doi 10 2307 4084566 JSTOR 4084566 del Hoyo Josep 1992 Family Phoenicopteridae Flamingos in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 1 Ostrich to Ducks Barcelona Lynx Edicions ISBN 978 84 87334 10 8 del Hoyo Josep Elliott Andrew Sargatal Jordi eds 1996 Handbook of Birds of the World vol 3 Barcelona Lynx Edicions ISBN 978 84 87334 20 7 Ehrlich Paul R Dobkin David S Wheye Darryl Pimm Stuart L 1994 The Birdwatcher s Handbook Oxford Oxford University Press ISBN 978 0 19 858407 0 Elliott Andrew 1994 Family Megapodiidae Megapodes in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 2 New World Vultures to Guineafowl Barcelona Lynx Edicions ISBN 978 84 87334 15 3 Gould James L Gould Carol Grant 2007 Animal Architects Building and the Evolution of Intelligence New York NY Basic Books ISBN 978 0 465 02782 8 Grant Gilbert 1982 Avian Incubation in a Hot Environment Ornithological Monographs vol 30 Washington DC American Ornithologists Union ISBN 978 0 943610 30 6 Haag Wackernagel D Moch H 2004 Health hazards posed by feral pigeons J Infect 48 4 307 313 doi 10 1016 j jinf 2003 11 001 PMID 15066331 Gill Frank B 1995 Ornithology Macmillan p 383 ISBN 978 0 7167 2415 5 retrieved 16 December 2009 Hansell Mike 2000 Bird Nests and Construction Behaviour Cambridge University Press ISBN 978 0 521 01764 0 Harrap Simon Quinn David 1996 Tits Nuthatches amp Treecreepers London Christopher Helm ISBN 978 0 7136 3964 3 Hogan C Michael 2010 Abiotic factor in Emily Monosson C Cleveland eds Encyclopedia of Earth Washington DC National Council for Science and the Environment archived from the original on 8 June 2013 Jaramillo Alvaro 2001 Blackbirds Orioles and Allies in Elphick Chris Dunning John B Jr Sibley David eds The Sibley Guide to Bird Life amp Behaviour London Christopher Helm ISBN 978 0 7136 6250 4 Juniper Tony Parr Mike 2003 Parrots A Guide to the Parrots of the World London Christopher Helm ISBN 978 0 7136 6933 6 Kaplan Gisela 2004 Australian Magpie Biology and Behaviour of an Unusual Songbird Melbourne Victoria CSIRO Publishing p 121 ISBN 978 0 643 09068 2 retrieved 16 December 2009 Kemp A C 2001 Family Bucerotidae Hornbills in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 6 Mousebirds to Hornbills Barcelona Lynx Edicions ISBN 978 84 87334 30 6 Petit Kenneth E Petit Lisa J Petit Daniel R 1989 Fecal Sac Removal Do the Pattern and Distance of Dispersal Affect the Chance of Nest Predation PDF The Condor 91 2 479 482 doi 10 2307 1368331 JSTOR 1368331 Reed J Michael 2001 Woodpeckers and Allies in Elphick Chris Dunning John B Jr Sibley David eds The Sibley Guide to Bird Life amp Behaviour London Christopher Helm ISBN 978 0 7136 6250 4 Rasmussen Pamela C Collar Nigel J 2002 Family Bucconidae Puffbirds in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 7 Jacamars to Woodpeckers Barcelona Lynx Edicions ISBN 978 84 87334 37 5 Rosenfeld R N Rosenfeld A J Gratson M W 1982 Unusual Nest Sanitation by a Broad Winged Hawk PDF The Wilson Bulletin 94 3 2365 366 Rudolph D C Kyle H Conner R N 1990 Red cockaded woodpeckers vs Rat Snakes The effectiveness of the resin barrier PDF Wilson Bull 102 l 14 22 Sabrosky Curtis W Bennett G F Whitworth T L 1989 Bird blow flies Protocalliphora Diptera Calliphoridae in North America with notes on the Palearctic species Washington DC Smithsonian Institution Press Schuetz Justin G 2005 Common waxbills use carnivore scat to reduce the risk of nest predation Behavioral Ecology 16 1 133 137 doi 10 1093 beheco arh139 archived from the original on 13 January 2013 Seng William J 2001 Flamingos in Elphick Chris Dunning John B Jr Sibley David eds The Sibley Guide to Bird Life amp Behaviour London Christopher Helm ISBN 978 0 7136 6250 4 Short Lester L Horne Jennifer F M 2002a Family Capitonidae Barbets in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 7 Jacamars to Woodpeckers Barcelona Lynx Edicions ISBN 978 84 87334 37 5 Short Lester L Horne Jennifer F M 2002b Family Indicatoridae Honeyguides in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 7 Jacamars to Woodpeckers Barcelona Lynx Edicions ISBN 978 84 87334 37 5 Skowron C Kern M 1980 The insulation in nests of selected North American songbirds Auk 97 4 816 824 doi 10 1093 auk 97 4 816 Ward P Zahavi A 1973 The importance of certain assemblages of birds as information centers for food finding Ibis 115 4 517 534 doi 10 1111 j 1474 919X 1973 tb01990 x Whittow F N Berger A J 1977 Heat loss from the nest of the Hawaiian honeycreeper Amakihi Wilson Bulletin 89 480 483 Wimberger P H 1984 The use of green plant material in bird nests to avoid ectoparasites PDF Auk 101 3 615 616 doi 10 1093 auk 101 3 615 Woodall Peter F 2001 Family Alcedinidae Kingfishers in del Hoyo Josep Elliott Andrew Sargatal Jordi eds Handbook of Birds of the World Volume 6 Mousebirds to Hornbills Barcelona Lynx Edicions ISBN 978 84 87334 30 6External links edit nbsp Wikimedia Commons has media related to Bird nests nbsp Wikisource has the text of the 1911 Encyclopaedia Britannica article Nidification Lecture notes on bird nesting Department of natural resources Illinois state Earthlife site on bird nests Point Reyes Bird Observatory Teacher Resource Packet Activity 4 Building Bird Nests Ingersoll Ernest 1920 Birds Nests of Encyclopedia Americana Nidification New International Encyclopedia 1905 Retrieved from https en wikipedia org w index php title Bird nest amp oldid 1216286041, wikipedia, wiki, book, books, library,

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