The roller coaster flight strategy of bar-headed geese conserves energy during Himalayan migrations
The physiological and biomechanical requirements of flight at high altitude have been the subject of much interest. Here, we uncover a steep relation between heart rate and wingbeat frequency (raised to the exponent 3.5) and estimated metabolic power and wingbeat frequency (exponent 7) of migratory...
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| Veröffentlicht in: | Science (American Association for the Advancement of Science) 2015-01, Vol.347 (6219), p.250-254 |
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| creator | Bishop, C. M. Spivey, R. J. Hawkes, L. A. Batbayar, N. Chua, B. Frappell, P. B. Milsom, W. K. Natsagdorj, T. Newman, S. H. Scott, G. R. Takekawa, J. Y. Wikelski, M. Butler, P. J. |
| description | The physiological and biomechanical requirements of flight at high altitude have been the subject of much interest. Here, we uncover a steep relation between heart rate and wingbeat frequency (raised to the exponent 3.5) and estimated metabolic power and wingbeat frequency (exponent 7) of migratory bar-headed geese. Flight costs increase more rapidly than anticipated as air density declines, which overturns prevailing expectations that this species should maintain high-altitude flight when traversing the Himalayas. Instead, a "roller coaster" strategy, of tracking the underlying terrain and discarding large altitude gains only to recoup them later in the flight with occasional benefits from orographic lift, is shown to be energetically advantageous for flights over the Himalayas. |
| doi_str_mv | 10.1126/science.1258732 |
| format | Article |
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M. ; Spivey, R. J. ; Hawkes, L. A. ; Batbayar, N. ; Chua, B. ; Frappell, P. B. ; Milsom, W. K. ; Natsagdorj, T. ; Newman, S. H. ; Scott, G. R. ; Takekawa, J. Y. ; Wikelski, M. ; Butler, P. J.</creator><creatorcontrib>Bishop, C. M. ; Spivey, R. J. ; Hawkes, L. A. ; Batbayar, N. ; Chua, B. ; Frappell, P. B. ; Milsom, W. K. ; Natsagdorj, T. ; Newman, S. H. ; Scott, G. R. ; Takekawa, J. Y. ; Wikelski, M. ; Butler, P. J.</creatorcontrib><description>The physiological and biomechanical requirements of flight at high altitude have been the subject of much interest. Here, we uncover a steep relation between heart rate and wingbeat frequency (raised to the exponent 3.5) and estimated metabolic power and wingbeat frequency (exponent 7) of migratory bar-headed geese. Flight costs increase more rapidly than anticipated as air density declines, which overturns prevailing expectations that this species should maintain high-altitude flight when traversing the Himalayas. 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Here, we uncover a steep relation between heart rate and wingbeat frequency (raised to the exponent 3.5) and estimated metabolic power and wingbeat frequency (exponent 7) of migratory bar-headed geese. Flight costs increase more rapidly than anticipated as air density declines, which overturns prevailing expectations that this species should maintain high-altitude flight when traversing the Himalayas. 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| source | American Association for the Advancement of Science; Jstor Complete Legacy; MEDLINE |
| subjects | Altitude Animal Migration Animal populations Animals Bioenergetics Biomechanical Phenomena Bird migration Body Temperature Body Weight Energy conservation Energy Metabolism Exponents Flight, Animal - physiology Geese - physiology Heart Rate Himalayas Migration Mountains Roller coasters Strategy Tibet Wildfowl Wings, Animal - physiology |
| title | The roller coaster flight strategy of bar-headed geese conserves energy during Himalayan migrations |
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