Calliope hummingbird explained

The calliope hummingbird (; Selasphorus calliope) is the smallest bird native to the United States and Canada.[1] It has a western breeding range mainly from California to British Columbia, and migrates to the Southwestern United States, Mexico, and Central America for its wintering grounds.[1] The calliope hummingbird is the smallest known long-distance bird migrant, completing migrations twice per year of some .[2]

It was previously considered the only member of the genus Stellula (meaning little star), but research evidence suggests its existing placement in the genus Selasphorus.[3] The bird was named after the Greek muse Calliope.

Description

The calliope is the smallest breeding bird found in Canada and the United States.[1] An adult calliope hummingbird can measure 7- in length, span 11cm (04inches) across the wings and weigh 2to.[4]

Calliope hummingbirds have glossy green on the back and crown with white underparts.[1] The adult male has wine-red streaks on the gorget, green flanks, and a dark tail.[1] When an adult male is competing for territory or females, the dark red feathers of its gorget distend outwards to create a more distinct appearance.[4] [5] Females and immatures have a pinkish wash on the flanks, dark streaks on the throat and a dark tail with white tips. The only similar birds are the rufous hummingbird and the Allen's hummingbird, but these birds are larger with more distinct and contrasting rufous markings on the tail and flanks, and longer central tail feathers.

Habitat and distribution

The breeding habitat of calliope hummingbird is varied among open shrub habitats and altitudes. Nesting usually occurs at higher altitudes in the Rocky Mountains. Nests have been observed from as low as 600feet in Oregon and Washington elevation to the tree line at over 11000feet.[4] In Montana, the minimum elevation observed for breeding is 1200m (3,900feet).[1] [4] Open montane forest, mountain meadows, and willow and alder thickets may variously serve as breeding grounds. During migration and winter, they also occur in chaparral, lowland brushy areas, deserts and semi-desert regions. They nest in western North America from southern British Columbia and Alberta south to Colorado and southern California.[2] During winter, they move mainly through Arizona and New Mexico and northern Mexico, to winter in southwestern Mexico.[2]

Behavior

Calliope hummingbirds are a migratory bird, generally leaving their breeding grounds earlier than most birds (although not as early as the rufous hummingbird) to take advantage of the late-summer wildflowers in the mountains of western North America. They are believed to be the smallest-bodied long distance migrant in the world.[4] [2]

These birds feed on nectar from flowers using a long extendable tongue, drink sap from holes created by sapsuckers or catch insects on the wing. While collecting nectar, they also assist in plant pollination.[1] Plants preferred for pollinating include paintbrush, penstemon, columbine, trumpet gilia, and elephant head. They will also occasionally catch and eat small insects and spiders.[4]

Adult males usually arrive on the breeding ground before females, from mid-April to early May. The male claims and vigorously defends a nesting territory in which he will breed with many females. The male takes no part in raising the young and often actually vacates the breeding grounds by the time the young hatch. The female usually builds an open cup nest in a conifer tree under an overhanging branch, though apple and alder trees have also been used. The nest is often built on the base of large pine cones and somewhat resembles a pine cone itself.[4] A nest may be used repeatedly over the course of several years. Two eggs are laid from late May to early July and are incubated for 15 to 16 days.[1] The young are capable of flight about 20 days after hatching.[4]

Humming

The prominent humming sound of a calliope hummingbird as for all hummingbirds during flight and hovering derives from its rapid wingbeats while feeding or interacting with other hummingbirds.[6] Humming serves as an audible communication to alert other birds of the arrival of a fellow forager or potential mate.[6] The humming sound derives from aerodynamic forces generated by both the downstrokes and upstrokes of the rapid wingbeats, producing acoustic oscillations and harmonics.[6]

Courtship display and sonation

During courtship, a male calliope hummingbird hovers at accelerated wingbeat frequency up to 95 flaps per second (42% higher than normal hovering), creating a loud buzzing sound, with throat feathers protruding and facing a female.[1] The male then ascends temporarily to and dives at high speed, with the rapid descent causing sonation of wing and tail feathers combined with vocalization, intending to attract attention of the female.[7] Research in a wind tunnel demonstrated that the male courtship display includessounds produced by three independent feather or vocal components, each with different acoustic characteristics, thus potentially containing different messages appealing to the female.[7] The tail feathers flutter at high frequency and hit each other to produce the buzzing sound.[8] Male calliope hummingbirds also make visual displays to females and nearby males by extending their purple gorget feathers to appear larger.[2]

Temperature regulation

The high metabolic rate of calliope hummingbirds  - especially during rapid forward flight and hovering  - produces increased body heat that requires specialized mechanisms of temperature regulation for dissipating heat, which becomes an even greater challenge in hot, humid climates.[9] As the smallest North American hummingbird species, calliopes appear to adapt their relatively higher surface-to-volume ratio to improve convective cooling from air movement by the wings.[9] When air temperatures rise above, thermal gradients driving heat passively by convective dissipation from around the eyes, shoulders, and feet are reduced or eliminated, requiring heat dissipation mainly by evaporation and exhalation.[9]

All hummingbirds dissipate heat partially by exhaled air, and from body structures with thin or no feather covering, such as around the eyes, shoulders, under the wings (patagia), and feet.[10] [11] While hovering, calliope hummingbirds do not benefit from the heat loss by air convection during forward flight, except for air movement generated by their rapid wing-beat, possibly aiding convective heat loss from the extended feet.[9] [12]

Status

As of 2019, calliope hummingbirds have a relatively stable breeding population of about 4.5 million.[4] As this species has a restricted wintering range in Mexico and travels an exceptional migratory distance annually of up to 9,000 km, it is on a watchlist for factors that could diminish the population.[4] [2]

Threats

The calliope hummingbird does not have many predators. Its biggest threat is likely long cold spells since they reduce the volume of insects and nectar available in its environment.[13] The calliope hummingbird may be aggressive in its territory with other hummingbird species and birds, including Wright Flycatchers, Western Robins, and Red-tailed Hawks.[2] [14]

Notes and References

  1. Web site: Calliope hummingbird . 13 November 2014 . National Audubon Society Birds. 31 May 2015.
  2. Web site: Stellula calliope: Calliope hummingbird . Animal Diversity Web, University of Michigan, Museum of Zoology . 27 April 2024 . 2020.
  3. McGuire, J.A. . Witt, C.C. . Remsen Jr., J.V. . Dudley, R. . Altshuler, D.L. . 2009 . A higher-level taxonomy for hummingbirds . Journal of Ornithology . 150 . 155–165 . 10.1007/s10336-008-0330-x. 1918245 .
  4. Web site: Calliope hummingbird. All About Birds, Laboratory of Ornithology, Cornell University. 2023. 24 October 2023.
  5. Web site: Calliope hummingbird, Stellula calliope (Gould); In: Animal Life in the Yosemite (The Birds) . National Park Service, US Government. 19 January 2006. 24 October 2023.
  6. Hightower . Ben J . Wijnings . Patrick WA . Scholte . Rick . Ingersoll . Rivers . Chin . Diana D . Nguyen . Jade . Shorr . Daniel . Lentink . David . How oscillating aerodynamic forces explain the timbre of the hummingbird's hum and other animals in flapping flight . eLife . 10 . 2021-03-16 . 2050-084X . 33724182 . 8055270 . 10.7554/elife.63107 . e63107 . free .
  7. Current Zoology. 57. 2. 187–196. 2011. Clark CJ. Wing, tail, and vocal contributions to the complex acoustic signals of courting Calliope hummingbirds. 10.1093/czoolo/57.2.187. dead. https://web.archive.org/web/20150716160821/http://www.actazool.org/temp/%7BACDC40CC-89E0-41E6-A4B2-7C7FB6734F1E%7D.pdf. 2015-07-16. free.
  8. Clark . CJ . Harmonic Hopping, and Both Punctuated and Gradual Evolution of Acoustic Characters in Selasphorus Hummingbird Tail-Feathers . PLOS ONE. 9 . 4 . 10 April 2014 . 1932-6203 . 24722049 . 3983109 . 10.1371/journal.pone.0093829 . e93829. 2014PLoSO...993829C . free .
  9. Powers . Donald R. . Langland . Kathleen M. . Wethington . Susan M. . Powers . Sean D. . Graham . Catherine H. . Tobalske . Bret W. . Hovering in the heat: effects of environmental temperature on heat regulation in foraging hummingbirds . Royal Society Open Science . 4 . 12 . 2017 . 2054-5703 . 10.1098/rsos.171056 . 171056. 5750011. 29308244.
  10. Evangelista . Dennis . Fernández . María José . Berns . Madalyn S. . Hoover . Aaron . Dudley . Robert . Hovering energetics and thermal balance in Anna's hummingbirds (Calypte anna) . Physiological and Biochemical Zoology . 83 . 3 . 2010 . 1522-2152 . 10.1086/651460 . 406–413. 20350142. 26974159 .
  11. Web site: Matt Soniak . Infrared video shows how hummingbirds shed heat through their eyes and feet . Mental Floss . 14 January 2020 . 2 February 2016.
  12. Miklos D F Udvardy . The role of the feet in behavioral thermoregulation of hummingbirds . Condor . 1983 . 85 . 3 . 281–5 . 10.2307/1367060 . 1367060 .
  13. California Interagency Wildlife Task Group . 1999 . Calliope Hummingbird . California's Wildlife . 1-3 . California Wildlife Habitat Relationships System.
  14. Web site: Animal Life in the Yosemite (Birds) . 2023-10-18 . www.nps.gov.