Activity Patterns of Bats During the Fall and Spring Along Ridgelines in the Central Appalachians

Muthersbaugh, Michael S.; Ford, W. Mark; Powers, Karen; Silvis, Alexander

doi:10.3996/082018-jfwm-072

Cited by 21 publications

(28 citation statements)

References 53 publications

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“…In birds, it has repeatedly been shown that the relative influence of different weather variables on migration phenology is strongly species‐dependent but also context‐dependent (Gordo, 2007; Haest et al., 2018b, 2019; Shaw, 2016), and a similarly diverse response to weather has been suggested for bats (Muthersbaugh et al., 2019). Therefore, future studies on other bat species and populations may find our results of wind being highly important for spring migration and precipitation for autumn migration timing to be specific for Brazilian free‐tailed bats.…”

Section: Discussionmentioning

confidence: 98%

“…This may explain why migration in Brazilian free‐tailed bats is not driven by temperature but by precipitation and wind—contrary to species in regions with more extreme inter‐seasonal temperature differences, for example, at higher latitudes. Some studies of migratory bats (at higher latitudes) in northern Europe or North America have indeed suggested that temperature plays an important role in migration timing (Jonasson & Guglielmo, 2019; Muthersbaugh et al., 2019; Pettit & O'Keefe, 2017; Roby et al., 2019; Rydell et al., 2014; Smith & McWilliams, 2016), although temperature was often investigated alone, neglecting possible precipitation and wind effects. However, it is possible that wind and precipitation become primary drivers of migratory timing in regions where a minimum temperature threshold for survivability is met throughout the migration period.…”

Section: Discussionmentioning

confidence: 99%

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Climatic drivers of (changes in) bat migration phenology at Bracken Cave (USA)

Haest

Stepanian

Wainwright

et al. 2020

Global Change Biology

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Climate change is drastically changing the timing of biological events across the globe. Changes in the phenology of seasonal migrations between the breeding and wintering grounds have been observed across biological taxa, including birds, mammals, and insects. For birds, strong links have been shown between changes in migration phenology and changes in weather conditions at the wintering, stopover, and breeding areas. For other animal taxa, the current understanding of, and evidence for, climate (change) influences on migration still remains rather limited, mainly due to the lack of long‐term phenology datasets. Bracken Cave in Texas (USA) holds one of the largest bat colonies of the world. Using weather radar data, a unique 23‐year (1995–2017) long time series was recently produced of the spring and autumn migration phenology of Brazilian free‐tailed bats (Tadarida brasiliensis) at Bracken Cave. Here, we analyse these migration phenology time series in combination with gridded temperature, precipitation, and wind data across Mexico and southern USA, to identify the climatic drivers of (changes in) bat migration phenology. Perhaps surprisingly, our extensive spatiotemporal search did not find temperature to influence either spring or autumn migration. Instead, spring migration phenology seems to be predominantly driven by wind conditions at likely wintering or spring stopover areas during the migration period. Autumn migration phenology, on the other hand, seems to be dominated by precipitation to the east and north‐east of Bracken Cave. Long‐term changes towards more frequent migration and favourable wind conditions have, furthermore, allowed spring migration to occur 16 days earlier. Our results illustrate how some of the remaining knowledge gaps on the influence of climate (change) on bat migration and abundance can be addressed using weather radar analyses.

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Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 99%

Climatic drivers of (changes in) bat migration phenology at Bracken Cave (USA)

Haest

Stepanian

Wainwright

et al. 2020

Global Change Biology

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“…As SDMs can be interpreted as conductance maps, we used an average of both spring and fall months (March, April, May and August, September, October, respectively) to assess potential corridors between winter and summer occurrences. These time periods are based on previously published distributions of occurrences (Cryan, 2003), previous SDM modeling (Hayes, Cryan & Wunder, 2015), wind farm fatality data (Arnett et al, 2008), radio telemetry (Walters et al, 2006), and acoustic data (Muthersbaugh et al, 2019). Using Circuitscape (Shah & McRae, 2008), we set our start ("source") and end ("ground") points based on the hypothesized direction of migration.…”

Section: Migratory Pathwaysmentioning

confidence: 99%

Predicting migration routes for three species of migratory bats using species distribution models

Wieringa

Carstens

Gibbs

2021

PeerJ

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Understanding seasonal variation in the distribution and movement patterns of migratory species is essential to monitoring and conservation efforts. While there are many species of migratory bats in North America, little is known about their seasonal movements. In terms of conservation, this is important because the bat fatalities from wind energy turbines are significant and may fluctuate seasonally. Here we describe seasonally resolved distributions for the three species that are most impacted by wind farms (Lasiurus borealis (eastern red bat), L. cinereus (hoary bat) and Lasionycteris noctivagans (silver-haired bat)) and use these distributions to infer their most likely migratory pathways. To accomplish this, we collected 2,880 occurrence points from the Global Biodiversity Information Facility over five decades in North America to model species distributions on a seasonal basis and used an ensemble approach for modeling distributions. This dataset included 1,129 data points for L. borealis, 917 for L. cinereus and 834 for L. noctivagans. The results suggest that all three species exhibit variation in distributions from north to south depending on season, with each species showing potential migratory pathways during the fall migration that follow linear features. Finally, we describe proposed migratory pathways for these three species that can be used to identify stop-over sites, assess small-scale migration and highlight areas that should be prioritized for actions to reduce the effects of wind farm mortality.

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“…These data provide further evidence that operational mitigation strategies at wind energy facilities could help protect migratory bat species and could be used to inform siting decisions for proposed wind energy facilities to lessen the potential impacts on migratory bats that use Appalachian ridges as their primary migration corridors. Publication Muthersbaugh, M.S., Ford, W.M., Powers, K.E., and Silvis, A., 2019, Activity patterns of bats during the fall and spring along ridgelines in the central Appalachians: Journal of Fish and Wildlife Management,v. 10,no.…”

Section: Pre-and Post-hibernation and Migratory Activity Of Bats In Tmentioning

confidence: 99%

U.S. Geological Survey energy and wildlife research annual report for 2019

2019

Circular

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Activity Patterns of Bats During the Fall and Spring Along Ridgelines in the Central Appalachians

Cited by 21 publications

References 53 publications

Climatic drivers of (changes in) bat migration phenology at Bracken Cave (USA)

Climatic drivers of (changes in) bat migration phenology at Bracken Cave (USA)

Predicting migration routes for three species of migratory bats using species distribution models

U.S. Geological Survey energy and wildlife research annual report for 2019

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