Seasonal influence of snow conditions on Dall’s sheep productivity in Wrangell-St Elias National Park and Preserve

Cosgrove, Christopher; Wells, Jeff; Nolin, A. W.; Putera, Judy; Prugh, Laura R.

doi:10.1371/journal.pone.0244787

Cited by 13 publications

(15 citation statements)

References 79 publications

(113 reference statements)

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“…In addition, we documented that climate variables influenced habitat selection through both direct and potentially indirect pathways. During spring and winter, sheep selected habitat with warmer air temperatures and lower snow depths, conditions that likely reduce energy expenditure via moderation of the thermal environment and reduction of energetic costs of movement [35,39,66]. Indirectly, climate is linked to the expansion of shrubs in alpine regions of southern Alaska [12], and shrub/scrub vegetation was significantly avoided by sheep during all seasons.…”

Section: Discussionmentioning

confidence: 99%

“…Severe weather events, such as icing and snow cover persisting into late spring, have reduced the amount of available habitat during critical periods potentially leading to declines in sheep populations across Alaska, including in Gates of the Arctic, Denali, and Lake Clark National Parks and Preserves [28,32,36]. Although previous studies have characterized seasonal patterns of habitat selection by Dall's sheep [20,25,37,38], only Mahoney et al [35] and Cosgrove et al [39] incorporated climate variables on a daily basis. Consequently, an…”

Section: Introductionmentioning

confidence: 99%

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Habitat selection by Dall’s sheep is influenced by multiple factors including direct and indirect climate effects

et al. 2021

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Arctic and boreal environments are changing rapidly, which could decouple behavioral and demographic traits of animals from the resource pulses that have shaped their evolution. Dall’s sheep (Ovis dalli dalli) in northwestern regions of the USA and Canada, survive long, severe winters and reproduce during summers with short growing seasons. We sought to understand the vulnerability of Dall’s sheep to a changing climate in Lake Clark National Park and Preserve, Alaska, USA. We developed ecological hypotheses about nutritional needs, security from predators, energetic costs of movement, and thermal shelter to describe habitat selection during winter, spring, and summer and evaluated habitat and climate variables that reflected these hypotheses. We used the synoptic model of animal space use to estimate parameters of habitat selection by individual females and calculated likelihoods for ecological hypotheses within seasonal models. Our results showed that seasonal habitat selection was influenced by multiple ecological requirements simultaneously. Across all seasons, sheep selected steep rugged areas near escape terrain for security from predators. During winter and spring, sheep selected habitats with increased forage and security, moderated thermal conditions, and lowered energetic costs of movement. During summer, nutritional needs and security influenced habitat selection. Climate directly influenced habitat selection during the spring lambing period when sheep selected areas with lower snow depths, less snow cover, and higher air temperatures. Indirectly, climate is linked to the expansion of shrub/scrub vegetation, which was significantly avoided in all seasons. Dall’s sheep balance resource selection to meet multiple needs across seasons and such behaviors are finely tuned to patterns of phenology and climate. Direct and indirect effects of a changing climate may reduce their ability to balance their needs and lead to continued population declines. However, several management approaches could promote resiliency of alpine habitats that support Dall’s sheep populations.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Habitat selection by Dall’s sheep is influenced by multiple factors including direct and indirect climate effects

et al. 2021

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“…Remotely sensed snow data may enable researchers to better balance the goal of assessing general, study area snowscape conditions (the second example GYE research question) with ensuring personnel safety and logistical efficiency. To this end, the research team may wish to identify other snow data collection methods that would allow remote monitoring for a longer time, such as a network of trail cameras and snow stakes to assess changes in depth throughout the fall, winter, and spring (Cosgrove et al, 2021;Sirén et al, 2018). This solution could eliminate human travel in avalanche-prone areas and allow for additional data collection.…”

Section: Box 7 Gye Examplementioning

confidence: 99%

“…For wildlife, snow properties can impact individuals by affecting movements and behaviors (Balkenhol et al, 2020; Berman et al, 2019; Boelman et al, 2017; Chimienti et al, 2020; Coady, 1974; Droghini & Boutin, 2018; Mahoney et al, 2018; Oliver et al, 2018; Oliver et al, 2020; Pedersen et al, 2021); predator–prey interactions (Horne et al, 2019; Nelson & Mech, 1986; Peers et al, 2020; Sirén et al, 2021); energetics related to foraging (Dumont et al, 2005; Fancy & White, 1985), locomotion (Fancy & White, 1987; Gurarie et al, 2019; Lundmark & Ball, 2008; Parker et al, 1984), and thermoregulation (Karniski, 2014; Pruitt Jr., 1957; Thompson III & Fritzell, 1988); forage accessibility (Hupp & Braun, 1989; Takatsuki et al, 1995; Visscher et al, 2006; White et al, 2009); as well as ground (Boelman et al, 2016) and subnivean habitat use (Bilodeau et al, 2013; Glass et al, 2021; Petty et al, 2015). Additionally, the effects of snow on individual survival (Hurley et al, 2017; Reinking et al, 2018; Shipley et al, 2020) and reproduction (Apollonio et al, 2013; Barnowe‐Meyer et al, 2011; Liston et al, 2016; Schmidt et al, 2019) can ultimately alter population‐level demographics (Apollonio et al, 2013; Berteaux et al, 2017; Boelman et al, 2019; Cosgrove et al, 2021; Desforges et al, 2021; Van de Kerk et al, 2018; Van de Kerk et al, 2020). Effective evaluation of such wildlife–snow relationships requires identification, acquisition, and incorporation of appropriate and relevant snow property information.…”

Section: Motivationmentioning

confidence: 99%

Collaborative wildlife–snow science: Integrating wildlife and snow expertise to improve research and management

et al. 2022

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For wildlife inhabiting snowy environments, snow properties such as onset date, depth, strength, and distribution can influence many aspects of ecology, including movement, community dynamics, energy expenditure, and forage accessibility. As a result, snow plays a considerable role in individual fitness and ultimately population dynamics, and its evaluation is, therefore, important for comprehensive understanding of ecosystem processes in regions experiencing snow. Such understanding, and particularly study of how wildlife–snow relationships may be changing, grows more urgent as winter processes become less predictable and often more extreme under global climate change. However, studying and monitoring wildlife–snow relationships continue to be challenging because characterizing snow, an inherently complex and constantly changing environmental feature, and identifying, accessing, and applying relevant snow information at appropriate spatial and temporal scales, often require a detailed understanding of physical snow science and technologies that typically lie outside the expertise of wildlife researchers and managers. We argue that thoroughly assessing the role of snow in wildlife ecology requires substantive collaboration between researchers with expertise in each of these two fields, leveraging the discipline‐specific knowledge brought by both wildlife and snow professionals. To facilitate this collaboration and encourage more effective exploration of wildlife–snow questions, we provide a five‐step protocol: (1) identify relevant snow property information; (2) specify spatial, temporal, and informational requirements; (3) build the necessary datasets; (4) implement quality control procedures; and (5) incorporate snow information into wildlife analyses. Additionally, we explore the types of snow information that can be used within this collaborative framework. We illustrate, in the context of two examples, field observations, remote‐sensing datasets, and four example modeling tools that simulate spatiotemporal snow property distributions and, in some cases, evolutions. For each type of snow data, we highlight the collaborative opportunities for wildlife and snow professionals when designing snow data collection efforts, processing snow remote sensing products, producing tailored snow datasets, and applying the resulting snow information in wildlife analyses. We seek to provide a clear path for wildlife professionals to address wildlife–snow questions and improve ecological inference by integrating the best available snow science through collaboration with snow professionals.

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“…Both ways are functionally equivalent because they apply a simple, scalarbased correction surface to the precipitation fluxes. In our calibration process, we chose to use SnowAssim to address the precipitation deficiencies in the reanalysis product, following the approach of other recent studies in mountainous regions of Alaska and following the original purpose of the SnowAssim model (Cosgrove et al, 2021, and their Calibration of SnowModel section; Liston and Heimstra, 2008;Young et al, 2020, and their Sect. 3.4).…”

Section: Calibrationmentioning

confidence: 99%

Assimilation of citizen science data in snowpack modeling using a new snow data set: Community Snow Observations

Crumley

Hill

Jones

et al. 2021

Hydrol. Earth Syst. Sci.

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Abstract. A physically based snowpack evolution and redistribution model was used to test the effectiveness of assimilating crowd-sourced snow depth measurements collected by citizen scientists. The Community Snow Observations (CSO; https://communitysnowobs.org/, last access: 11 August 2021) project gathers, stores, and distributes measurements of snow depth recorded by recreational users and snow professionals in high mountain environments. These citizen science measurements are valuable since they come from terrain that is relatively undersampled and can offer in situ snow information in locations where snow information is sparse or nonexistent. The present study investigates (1) the improvements to model performance when citizen science measurements are assimilated, and (2) the number of measurements necessary to obtain those improvements. Model performance is assessed by comparing time series of observed (snow pillow) and modeled snow water equivalent values, by comparing spatially distributed maps of observed (remotely sensed) and modeled snow depth, and by comparing fieldwork results from within the study area. The results demonstrate that few citizen science measurements are needed to obtain improvements in model performance, and these improvements are found in 62 % to 78 % of the ensemble simulations, depending on the model year. Model estimations of total water volume from a subregion of the study area also demonstrate improvements in accuracy after CSO measurements have been assimilated. These results suggest that even modest measurement efforts by citizen scientists have the potential to improve efforts to model snowpack processes in high mountain environments, with implications for water resource management and process-based snow modeling.

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Seasonal influence of snow conditions on Dall’s sheep productivity in Wrangell-St Elias National Park and Preserve

Cited by 13 publications

References 79 publications

Habitat selection by Dall’s sheep is influenced by multiple factors including direct and indirect climate effects

Habitat selection by Dall’s sheep is influenced by multiple factors including direct and indirect climate effects

Collaborative wildlife–snow science: Integrating wildlife and snow expertise to improve research and management

Assimilation of citizen science data in snowpack modeling using a new snow data set: Community Snow Observations

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