Making movement ecology into a predictive science

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Abstract

1. Movement allows animals to change their environmental surroundings and remain in suitable conditions. As environments shift, e.g. through predictable seasonal progression, individuals can adapt their movement strategies accordingly. However, novel climate change introduces unpredictable, atypical conditions (e.g. droughts, floods), which may drive distinct movement responses. Predicting how future conditions will affect these movement decisions requires a better understanding of how such environmental variability shapes animal movements. 2. Gaining predictive power in movement ecology requires establishing a baseline understanding of movements during typical conditions and responses to within-the-norm shifts in conditions. We propose that animals respond along different axes to changes in conditions, adjusting when, where, and how they move as different components of their environment change. Integrating responses across these three movement axes provides a powerful framework for identifying when change occurs (e.g. animals moving outside of their typical movement 'envelope') and for inferring the type of environmental change based on which axes are affected. 3. We propose a framework to detect ecologically meaningful environmental shifts, identify the type of change, and use animals as sentinels of novel environmental conditions. By comparing movement responses under predictable and unpredictable conditions, this framework enables the identification of key environmental elements or habitat features that are critical for survival. Such insight improves our ability to predict how species will be affected by—and respond to—future climate change. 4. Coupling large-scale, real-time animal tracking with our predictive movement ecology framework unlocks the potential to use animals as sentinels for detecting rapid and unpredictable environmental changes. Advancing movement ecology into a predictive science is essential for addressing questions about the impacts of novel environmental conditions on animals.
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This is a Preprint and has not been peer reviewed. This is version 1 of this Preprint. You must log in to post a comment. There are no comments or no comments have been made public for this article. This is a Preprint and has not been peer reviewed. This is version 1 of this Preprint. Add a Comment You must log in to post a comment. Comments There are no comments or no comments have been made public for this article. 1. Movement allows animals to change their environmental surroundings and remain in suitable conditions. As environments shift, e.g. through predictable seasonal progression, individuals can adapt their movement strategies accordingly. However, novel climate change introduces unpredictable, atypical conditions (e.g. droughts, floods), which may drive distinct movement responses. Predicting how future conditions will affect these movement decisions requires a better understanding of how such environmental variability shapes animal movements. 2. Gaining predictive power in movement ecology requires establishing a baseline understanding of movements during typical conditions and responses to within-the-norm shifts in conditions. We propose that animals respond along different axes to changes in conditions, adjusting when, where, and how they move as different components of their environment change. Integrating responses across these three movement axes provides a powerful framework for identifying when change occurs (e.g. animals moving outside of their typical movement 'envelope') and for inferring the type of environmental change based on which axes are affected. 3. We propose a framework to detect ecologically meaningful environmental shifts, identify the type of change, and use animals as sentinels of novel environmental conditions. By comparing movement responses under predictable and unpredictable conditions, this framework enables the identification of key environmental elements or habitat features that are critical for survival. Such insight improves our ability to predict how species will be affected by—and respond to—future climate change. 4. Coupling large-scale, real-time animal tracking with our predictive movement ecology framework unlocks the potential to use animals as sentinels for detecting rapid and unpredictable environmental changes. Advancing movement ecology into a predictive science is essential for addressing questions about the impacts of novel environmental conditions on animals. https://doi.org/10.32942/X2TW82 Ecology and Evolutionary Biology animal movement, animal tracking, environmental variability, habitat shifts, long-term studies, movement ecology Published: 2026-02-16 04:24 Last Updated: 2026-02-16 04:24 CC-By Attribution-NonCommercial-NoDerivatives 4.0 International Conflict of interest statement: None Data and Code Availability Statement: Not applicable Language: English

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