Human and animal movements combine with snow to increase moose-vehicle collisions in winter

Wildlife-vehicle collisions imperil humans, wildlife, and property. Collisions with moose (Alces alces ) are especially consequential and there are indications they may increase during severe winters. We tested hypotheses regarding the influence of moose movements and vehicular traffic patterns on c...

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Bibliographic Details
Published in:Environmental Research Letters
Main Authors: Calum X Cunningham, Glen E Liston, Adele K Reinking, Natalie T Boelman, Todd J Brinkman, Kyle Joly, Mark Hebblewhite, Stan Boutin, Sophie Czetwertynski, Leonard E Sielecki, Laura R Prugh
Format: Article in Journal/Newspaper
Language:English
Published: IOP Publishing 2022
Subjects:
wildlife-vehicle collisions
animal-vehicle collisions
anthropogenic effects
migration
human-wildlife conflict
Arctic boreal vulnerability experiment
Environmental technology. Sanitary engineering
TD1-1066
Environmental sciences
GE1-350
Science
Q
Physics
QC1-999
Arctic
Alces alces
Moose
Online Access:https://doi.org/10.1088/1748-9326/aca8bf
https://doaj.org/article/5256e01aae484f0dad6b69c3b876f53d
Description
Summary:Wildlife-vehicle collisions imperil humans, wildlife, and property. Collisions with moose (Alces alces ) are especially consequential and there are indications they may increase during severe winters. We tested hypotheses regarding the influence of moose movements and vehicular traffic patterns on collision risk. We first modeled daily snow depth and accumulation across 5.6 million km ^2 of the North American Arctic-Boreal region. Next, we analyzed the movements and road use of 113 GPS-collared moose in response to snow depth. Finally, we examined the influence of these snow properties on vehicular traffic and 7680 moose-vehicle collisions. As winter progressed and the snowpack deepened in each study area, GPS-collared moose migrated to lower elevations, leading them into areas with shallower snow but higher road densities. This elevational migration corresponded with a higher probability of road-use by moose (by up to ten-fold) in winter than in summer. Corresponding to these patterns, moose-vehicle collisions were 2.4–5.7 times more frequent from December through February (compared to early summer). Collision risk was highest when and where snow depth was less than 120 cm, indicating that migration into areas with shallower snow increased collision risk in those areas. Most (82%) moose-vehicle collisions occurred after dark. This pattern was strongest during winter, when nighttime traffic volumes were eight times higher than summer due to longer nights. Overall, our findings suggest that concurrent seasonal changes in human and wildlife behavior increase the frequency of moose-vehicle collisions during winter. Snow depth influences collisions primarily through its impacts on moose movement, while strong seasonal changes in daylight hours cause an increase in nighttime traffic that further contributes to risk. This information may help predict times and places where risk of moose-vehicle collisions are highest and to develop seasonally dynamic mitigation strategies.

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