北方雨燕的风力辅助冲刺式迁徙。

Wind-assisted sprint migration in northern swifts.

作者信息

Åkesson Susanne, Bianco Giuseppe

机构信息

Department of Biology, Centre for Animal Movement Research, Lund University, Ecology Building, 223 62 Lund, Sweden.

出版信息

iScience. 2021 May 20;24(6):102474. doi: 10.1016/j.isci.2021.102474. eCollection 2021 Jun 25.

DOI:10.1016/j.isci.2021.102474

PMID:34308278

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8257983/

Abstract

Long-distance migration has evolved repeatedly in animals and covers substantial distances across the globe. The overall speed of migration in birds is determined by fueling rate at stopover, flight speed, power consumption during flight, and wind support. The highest speeds (500 km/day) have been predicted in small birds with a fly-and-forage strategy, such as swallows and swifts. Here, we use GLS tracking data for common swifts breeding in the northern part of the European range to study seasonal migration strategies and overall migration speeds. The data reveal estimated overall migration speeds substantially higher (average: 570 km/day; maximum: 832 km/day over 9 days) than predicted for swifts. In spring, swift routes provided 20% higher tailwind support than in autumn. Sustained migration speeds of this magnitude can only be achieved in small birds by a combined strategy including high fueling rate at stopover, fly-and-forage during migration, and selective use of tailwinds.

摘要

长途迁徙在动物中反复进化，跨越全球的距离相当可观。鸟类迁徙的总体速度取决于中途停歇时的进食速度、飞行速度、飞行过程中的能量消耗以及风力支持。采用边飞边觅食策略的小鸟，如燕子和雨燕，预计飞行速度最高（每天500公里）。在这里，我们利用在欧洲分布范围北部繁殖的普通雨燕的GLS跟踪数据，研究其季节性迁徙策略和总体迁徙速度。数据显示，普通雨燕的估计总体迁徙速度（平均：每天570公里；9天内最高：每天832公里）大大高于预测速度。在春季，雨燕的路线所获得的顺风支持比秋季高20%。只有通过包括中途停歇时高进食速度、迁徙过程中边飞边觅食以及选择性利用顺风在内的综合策略，小鸟才能实现这种持续的迁徙速度。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/61b1/8257983/effa00a818a4/fx1.jpg

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北方雨燕的风力辅助冲刺式迁徙。

Wind-assisted sprint migration in northern swifts.

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