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Tracking suitable habitat for tree populations under climate change in western North America

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  • Laura Gray
  • Andreas Hamann

Abstract

An important criticism of bioclimate envelope models is that many wide-ranging species consist of locally adapted populations that may all lag behind their optimal climate habitat under climate change, and thus should be modeled separately. Here, we apply a bioclimate envelope model that tracks habitat of individual populations to estimate adaptational lags for 15 wide-ranging forest tree species in western North America. An ensemble classifier modeling approach (RandomForest) was used to spatially project the climate space of tree populations under observed climate trends (1970s to 2000s) and multi-model projections for the 2020s, 2050s and 2080s. We find that, on average, populations already lag behind their optimal climate niche by approximately 130 km in latitude, or 60 m in elevation. For the 2020s we expect an average lag of approximately 310 km in latitude or 140 m in elevation, with the most pronounced geographic lags in the Rocky Mountains and the boreal forest. We show that our results could in principle be applied to guide assisted migration of planting stock in reforestation programs using a general formula where 100 km north shift is equivalent to approximately 44 m upward shift in elevation. However, additional non-climatic factors should be considered when matching reforestation stock to suitable planting environments. Copyright Springer Science+Business Media B.V. 2013

Suggested Citation

  • Laura Gray & Andreas Hamann, 2013. "Tracking suitable habitat for tree populations under climate change in western North America," Climatic Change, Springer, vol. 117(1), pages 289-303, March.
    • Handle: RePEc:spr:climat:v:117:y:2013:i:1:p:289-303
    DOI: 10.1007/s10584-012-0548-8
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    References listed on IDEAS

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    1. Valerie A. Barber & Glenn Patrick Juday & Bruce P. Finney, 2000. "Reduced growth of Alaskan white spruce in the twentieth century from temperature-induced drought stress," Nature, Nature, vol. 405(6787), pages 668-673, June.
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    1. Emma L. Davis & Robert Brown & Lori Daniels & Trudy Kavanagh & Ze’ev Gedalof, 2020. "Regional variability in the response of alpine treelines to climate change," Climatic Change, Springer, vol. 162(3), pages 1365-1384, October.
    2. Mathys, A.S. & Coops, N.C. & Simard, S.W. & Waring, R.H. & Aitken, S.N., 2018. "Diverging distribution of seedlings and mature trees reflects recent climate change in British Columbia," Ecological Modelling, Elsevier, vol. 384(C), pages 145-153.
    3. King, David A. & Bachelet, Dominique M. & Symstad, Amy J. & Ferschweiler, Ken & Hobbins, Michael, 2015. "Estimation of potential evapotranspiration from extraterrestrial radiation, air temperature and humidity to assess future climate change effects on the vegetation of the Northern Great Plains, USA," Ecological Modelling, Elsevier, vol. 297(C), pages 86-97.
    4. Maximilian Axer & Robert Schlicht & Rico Kronenberg & Sven Wagner, 2021. "The Potential for Future Shifts in Tree Species Distribution Provided by Dispersal and Ecological Niches: A Comparison between Beech and Oak in Europe," Sustainability, MDPI, vol. 13(23), pages 1-20, November.

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