Little directional change in the timing of Arctic spring phenology over the past 25 years

Summary With the global change in climate, the Arctic has been pinpointed as the region experiencing the fastest rates of change. As a result, Arctic biological responses—such as shifts in phenology—are expected to outpace those at lower latitudes. 15 years ago, a decade-long dataset from Zackenberg...

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Bibliographic Details
Published in:Current Biology
Main Authors: Schmidt, Niels Martin, Kankaanpää, Tuomas, Tiusanen, Mikko, Reneerkens, Jeroen, Versluijs, Tom S.L., Hansen, Lars Holst, Hansen, Jannik, Gerlich, Hannah Sørine, Høye, Toke T., Cirtwill, Alyssa R., Zhemchuzhnikov, Mikhail K., Peña-Aguilera, Pablo, Roslin, Tomas
Format: Article in Journal/Newspaper
Language:English
Published: 2023
Subjects:
arthropods
birds
climate
emergence
flowering
plants
reproduction
snow
Temperature
Animals
Climate Change
Arctic Regions
Flowers/physiology
Seasons
Arctic
Greenland
Climate change
Zackenberg
Online Access:https://pure.au.dk/portal/en/publications/56a44e39-03d6-4dc1-9d4f-a09c319ed511
https://doi.org/10.1016/j.cub.2023.06.038
http://www.scopus.com/inward/record.url?scp=85167480068&partnerID=8YFLogxK
https://www.sciencedirect.com/science/article/pii/S0960982223008230
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Summary:Summary With the global change in climate, the Arctic has been pinpointed as the region experiencing the fastest rates of change. As a result, Arctic biological responses—such as shifts in phenology—are expected to outpace those at lower latitudes. 15 years ago, a decade-long dataset from Zackenberg in High Arctic Greenland revealed rapid rates of phenological change.1 To explore how the timing of spring phenology has developed since, we revisit the Zackenberg time series on flowering plants, arthropods, and birds. Drawing on the full 25-year period of 1996–2020, we find little directional change in the timing of events despite ongoing climatic change. We attribute this finding to a shift in the temporal patterns of climate conditions, from previous directional change to current high inter-annual variability. Additionally, some taxa appear to have reached the limits of their phenological responses, resulting in a leveling off in their phenological responses in warm years. Our findings demonstrate the importance of long-term monitoring of taxa from across trophic levels within the community, allowing for detecting shifts in sensitivities and responses and thus for updated inference in the light of added information. With the global change in climate, the Arctic has been pinpointed as the region experiencing the fastest rates of change. As a result, Arctic biological responses—such as shifts in phenology—are expected to outpace those at lower latitudes. 15 years ago, a decade-long dataset from Zackenberg in High Arctic Greenland revealed rapid rates of phenological change. 1 To explore how the timing of spring phenology has developed since, we revisit the Zackenberg time series on flowering plants, arthropods, and birds. Drawing on the full 25-year period of 1996–2020, we find little directional change in the timing of events despite ongoing climatic change. We attribute this finding to a shift in the temporal patterns of climate conditions, from previous directional change to current high inter-annual ...

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