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Estimating the vulnerability of fifteen tree species under changing climate in Northwest North America

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  • Coops, Nicholas C.
  • Waring, Richard H.

Abstract

In the Pacific northwestern (PNW) region of North America, climatic conditions have significantly warmed since a predominantly cool phase of the Pacific North American circulation patterns between 1950 and 1975. What are the implications of this shift in climate for the vulnerability of native tree species? To address this question, we combined mechanistic and statistical models to assess where a variety of native tree species might be more vulnerable within their recorded ranges and where they might potentially migrate. For long-lived species that are well adapted to compete, seasonal differences in photosynthesis and water use offer insights helpful in predicting their distributions. To evaluate the general response of conifers to climatic variation across the region, we previously applied a process-based model (3-PG), to simulate the growth and maximum leaf area index that Douglas-fir could attain within recognized forested areas. We then constructed automated decision tree models to define and map the ecological distributions of 15 tree species based on differences in how photosynthesis was constrained by drought, daytime temperatures, high evaporative demand, and the frequency of frost. For the baseline climate period (1950–1975), the decision tree models predicted presence and absence of each species at ∼23,000 observations with an average accuracy of 81%, with an average kappa statistic of 0.74. In this paper the same models were run annually for the period between 1976 and 2006 for each species, and the areas defined as remaining suitable or becoming vulnerable to disturbance were identified based on whether more or less than half of the years fell within the originally defined limits. Based on these criteria, 70% of the species recorded ranges remained suitable, with 30% deemed vulnerable. Results varied notably by species with western red cedar and western hemlock remaining highly adapted, with potential for range expansion in area of up to 50% relative to the baseline period. In contrast, ponderosa pine, lodgepole pine, grand, and noble fir were classified as vulnerable with potential net contractions in their ranges. The analysis was extended through the rest of the 21st century using climatic projections from the Canadian global circulation model with a high fossil fuel emission scenario (A2) and compared to other previously published species range predictions.

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  • Coops, Nicholas C. & Waring, Richard H., 2011. "Estimating the vulnerability of fifteen tree species under changing climate in Northwest North America," Ecological Modelling, Elsevier, vol. 222(13), pages 2119-2129.
    • Handle: RePEc:eee:ecomod:v:222:y:2011:i:13:p:2119-2129
    DOI: 10.1016/j.ecolmodel.2011.03.033
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    References listed on IDEAS

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    1. W. A. Kurz & C. C. Dymond & G. Stinson & G. J. Rampley & E. T. Neilson & A. L. Carroll & T. Ebata & L. Safranyik, 2008. "Mountain pine beetle and forest carbon feedback to climate change," Nature, Nature, vol. 452(7190), pages 987-990, April.
    2. -, 2008. "Women and Water: Climate Change in the Caribbean," Sede Subregional de la CEPAL para el Caribe (Estudios e Investigaciones) 38435, Naciones Unidas Comisión Económica para América Latina y el Caribe (CEPAL).
    3. Nitschke, Craig R. & Innes, John L., 2008. "A tree and climate assessment tool for modelling ecosystem response to climate change," Ecological Modelling, Elsevier, vol. 210(3), pages 263-277.
    4. Coops, Nicholas C. & Waring, Richard H. & Schroeder, Todd A., 2009. "Combining a generic process-based productivity model and a statistical classification method to predict the presence and absence of tree species in the Pacific Northwest, U.S.A," Ecological Modelling, Elsevier, vol. 220(15), pages 1787-1796.
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    1. Sheehan, T. & Bachelet, D. & Ferschweiler, K., 2015. "Projected major fire and vegetation changes in the Pacific Northwest of the conterminous United States under selected CMIP5 climate futures," Ecological Modelling, Elsevier, vol. 317(C), pages 16-29.
    2. Michael J. Case & Joshua J. Lawler, 2016. "Relative vulnerability to climate change of trees in western North America," Climatic Change, Springer, vol. 136(2), pages 367-379, May.
    3. Dymond, Caren Christine & Giles-Hansen, Krysta & Asante, Patrick, 2020. "The forest mitigation-adaptation nexus: Economic benefits of novel planting regimes," Forest Policy and Economics, Elsevier, vol. 113(C).
    4. David Turner & David Conklin & John Bolte, 2015. "Projected climate change impacts on forest land cover and land use over the Willamette River Basin, Oregon, USA," Climatic Change, Springer, vol. 133(2), pages 335-348, November.
    5. Gupta, Rajit & Sharma, Laxmi Kant, 2019. "The process-based forest growth model 3-PG for use in forest management: A review," Ecological Modelling, Elsevier, vol. 397(C), pages 55-73.

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