Influence of weather conditions on the flight of migrating black storks

Chevallier, Damien; Handrich, Yves; Georges, Jean‐Yves; Baillon, François; Paul, Brossault; Aurouet, Axel; Maho, Yvon Le; Massemin, Sylvie

doi:10.1098/rspb.2010.0422

Cited by 57 publications

(66 citation statements)

References 43 publications

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“…Some of the greatest savings in movement energy will occur when particular locomotion options allow animals to negotiate what is otherwise an impenetrable object, such as a cliff or a body of water (Chevallier et al 2010). One of the selection pressures for flight illustrates this well and shows the dangers of comparing COT for animals moving through idealized landscapes in or on different media at a constant height.…”

Section: Expectations For General Animal Movement Strategies In Energmentioning

confidence: 99%

Energy Landscapes Shape Animal Movement Ecology

Shepard

Wilson²,

Rees³

et al. 2013

The American Naturalist

325

374

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JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. Submitted January 5, 2013; Accepted April 11, 2013; Electronically published July 12, 2013 abstract: The metabolic costs of animal movement have been studied extensively under laboratory conditions, although frequently these are a poor approximation of the costs of operating in the natural, heterogeneous environment. Construction of "energy landscapes," which relate animal locality to the cost of transport, can clarify whether, to what extent, and how movement properties are attributable to environmental heterogeneity. Although behavioral responses to aspects of the energy landscape are well documented in some fields (notably, the selection of tailwinds by aerial migrants) and scales (typically large), the principles of the energy landscape extend across habitat types and spatial scales. We provide a brief synthesis of the mechanisms by which environmentally driven changes in the cost of transport can modulate the behavioral ecology of animal movement in different media, develop example cost functions for movement in heterogeneous environments, present methods for visualizing these energy landscapes, and derive specific predictions of expected outcomes from individual-to population-and species-level processes. Animals modulate a suite of movement parameters (e.g., route, speed, timing of movement, and tortuosity) in relation to the energy landscape, with the nature of their response being related to the energy savings available. Overall, variation in movement costs influences the quality of habitat patches and causes nonrandom movement of individuals between them. This can provide spatial and/or temporal structure to a range of population-and specieslevel processes, ultimately including gene flow. Advances in animalattached technology and geographic information systems are opening up new avenues for measuring and mapping energy landscapes that are likely to provide new insight into their influence in animal ecology.

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Section: Expectations For General Animal Movement Strategies In Energmentioning

confidence: 99%

Energy Landscapes Shape Animal Movement Ecology

Shepard

Wilson²,

Rees³

et al. 2013

The American Naturalist

325

374

View full text Add to dashboard Cite

show abstract

“…However, the adaptability of these routes is not fully understood, mainly because of the difficulty of measuring variables that may determine travelling patterns at sufficiently large time and spatial scales. For example, if weather conditions determine patterns of avian movement, we must accurately measure the spatiotemporal dynamics of weather conditions with high resolution, and then superimpose the routes of travel on these weather maps as well as statistically examine the effect of weather conditions on migration routes, body conditions of birds and flight strategies such as which flight style is adopted or when, where and how long a bird stops over (Shamoun-Baranes et al 2003, 2010Mandel et al 2008;Chevallier et al 2010;Mandel et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Real-time weather analysis reveals the adaptability of direct sea-crossing by raptors

Yamaguchi

Arisawa

Shimada

et al. 2011

J Ethol

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Many animals seasonally travel between their breeding and wintering grounds. With their advanced mobility, birds often migrate over thousands of kilometres. Recently, satellite-tracking studies have revealed peculiar migration routes for some avian species at a global scale. However, the adaptability of such migration routes has not been clearly demonstrated. Using satellite-tracking data for 33 individuals, we show that the Japanese population of Oriental honey-buzzards (Pernis ptilorhynchus) directly crosses the 650-km-wide East China Sea during their autumn migration, although they fly a longer route around the sea rather than directly crossing it during their spring migration. By applying aerodynamic theory, we show that the buzzards could cross the sea by soaring and gliding flight. Moreover, using a high-resolution meteorologicalprediction analysis, we demonstrate that the migratory trajectory of the birds strongly depends on the wind direction at their estimated locations. In the area, northeastern tailwinds blow stably only during autumn. Thermals were abundant ca. 500-1,000 m over the East China Sea in autumn, but that was not the case in spring. We suggest that the autumnmigration route across the East China Sea is likely to have evolved in response to the specific weather conditions over the sea. Animations showing movements of Oriental honeybuzzards and temporal change in weather conditions are available at:

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“…By comparison, both early morning and late afternoon passage were low under weak winds, typically with NE winds; even though passage did increase by midday under these conditions, overall passage on these days was much lower than seen during high-wind conditions. Under such low-wind conditions, birds may not be able to initiate movement until thermal activity on the ridgelines, which is not present when strong winds dissipate warm, rising pockets of air (Shamoun-Baranes et al 2003, Ákos et al 2008, Chevallier et al 2010, Duerr et al 2012, begins to peak at midday. However, whether eagles respond to strong winds by taking flight earlier in the day or to weak winds and thermal activity by concentrating movement later in the morning, both scenarios attest to the overwhelming importance of documenting spatial and temporal patterns of movement to identify conditions of collision risk.…”

Section: Discussionmentioning

confidence: 99%

Flight Paths of Migrating Golden Eagles and the Risk Associated with Wind Energy Development in the Rocky Mountains

Johnston¹,

Bradley²,

Pomeroy³

et al. 2013

ACE

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ABSTRACT. In recent years, the eastern foothills of the Rocky Mountains in northeastern British Columbia have received interest as a site of industrial wind energy development but, simultaneously, have been the subject of concern about wind development coinciding with a known migratory corridor of Golden Eagles (Aquila chrysaetos). We tracked and quantified eagle flights that crossed or followed ridgelines slated for one such wind development. We found that hourly passage rates during fall migration peaked at midday and increased by 17% with each 1 km/h increase in wind speed and by 11% with each 1°C increase in temperature. The propensity to cross the ridge tops where turbines would be situated differed between age classes, with juvenile eagles almost twice as likely to traverse the ridge-top area as adults or subadults. During fall migration, Golden Eagles were more likely to cross ridges at turbine heights (risk zone, < 150 m above ground) under headwinds or tailwinds, but this likelihood decreased with increasing temperature. Conversely, during spring migration, eagles were more likely to move within the ridge-top area under eastern crosswinds. Identifying Golden Eagle flight routes and altitudes with respect to major weather systems and local topography in the Rockies may help identify scenarios in which the potential for collisions is greatest at this and other installations.RÉSUMÉ. Récemment, les contreforts des Rocheuses dans le nord-est de la Colombie-Britannique ont attiré l'attention comme site potentiel d'un développement éolien industriel, tout en faisant simultanément l'objet de préoccupations puisque ce projet coïnciderait avec un corridor de migration connu d'Aigles royaux (Aquila chrysaetos). Nous avons suivi et quantifié les vols d'aigles qui ont traversé ou longé les lignes de crêtes visées par un projet éolien de ce genre. Nous avons constaté que le taux de passage horaire durant la migration automnale atteignait un maximum à midi et augmentait de 17 % pour chaque km/h d'augmentation de la vitesse du vent, et de 11 % pour chaque °C d'augmentation de la température. La propension à traverser les sommets des crêtes où seraient installées les éoliennes différait selon les classes d'âge, les jeunes aigles de l'année ayant deux fois plus de chance de le faire que les adultes ou les jeunes plus âgés. Durant la migration automnale, les aigles traversaient davantage les crêtes à hauteur d'éoliennes (zone de risque, < 150 m au-dessus du niveau du sol) sous un vent de face ou arrière, mais cette tendance diminuait avec l'augmentation de la température. En revanche, durant la migration printanière, les aigles étaient plus susceptibles de survoler la région des sommets sous un vent latéral de l'est. La détermination des trajectoires et des altitudes de vol des Aigles royaux, selon les systèmes météorologiques prédominants et la topographie locale des Rocheuses, peut contribuer à identifier les scénarios dans lesquels les risques de collision sont les plus élevés, que ce soit pour ce projet éolien ou d'au...

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Influence of weather conditions on the flight of migrating black storks

Cited by 57 publications

References 43 publications

Energy Landscapes Shape Animal Movement Ecology

Energy Landscapes Shape Animal Movement Ecology

Real-time weather analysis reveals the adaptability of direct sea-crossing by raptors

Flight Paths of Migrating Golden Eagles and the Risk Associated with Wind Energy Development in the Rocky Mountains

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