Ecological forecasting of tree growth: Regional fusion of tree‐ring and forest inventory data to quantify drivers and characterize uncertainty

Ecological forecasting of tree growth: Regional fusion of tree‐ring and forest inventory data to quantify drivers and characterize uncertainty

Robust ecological forecasting of tree growth under future climate conditions is critical to anticipate future forest carbon storage and flux. Here, we apply three ingredients of ecological forecasting that are key to improving forecast skill: data fusion, confronting model predictions with new data,...

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Bibliographic Details
Published in:Global change biology Vol. 28; no. 7; pp. 2442 - 2460
Main Authors: Heilman, Kelly A., Dietze, Michael C., Arizpe, Alexis A., Aragon, Jacob, Gray, Andrew, Shaw, John D., Finley, Andrew O., Klesse, Stefan, DeRose, R. Justin, Evans, Margaret E. K.
Format: Journal Article
Language:English
Published: England Blackwell Publishing Ltd 01-04-2022
Subjects:
Bayes Theorem
Bayesian analysis
Carbon
Carbon capture and storage
Carbon sequestration
Climate Change
Climate effects
Climatic conditions
Complementarity
data fusion
Data integration
Diameters
Ecological effects
ecological forecasting
Environmental accounting
Forecasting
forest
forest inventory
Forests
Growth models
Initial conditions
Iterative methods
Mathematical models
Partitioning
Pine trees
Pinus
ponderosa pine
Probability theory
Process parameters
Regional analysis
Robustness
tree ring
Uncertainty
Vulnerability
data fusion
forest
ponderosa pine
forest inventory
ecological forecasting
tree ring
climate change
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Summary:Robust ecological forecasting of tree growth under future climate conditions is critical to anticipate future forest carbon storage and flux. Here, we apply three ingredients of ecological forecasting that are key to improving forecast skill: data fusion, confronting model predictions with new data, and partitioning forecast uncertainty. Specifically, we present the first fusion of tree‐ring and forest inventory data within a Bayesian state‐space model at a multi‐site, regional scale, focusing on Pinus ponderosa var. brachyptera in the southwestern US. Leveraging the complementarity of these two data sources, we parsed the ecological complexity of tree growth into the effects of climate, tree size, stand density, site quality, and their interactions, and quantified uncertainties associated with these effects. New measurements of trees, an ongoing process in forest inventories, were used to confront forecasts of tree diameter with observations, and evaluate alternative tree growth models. We forecasted tree diameter and increment in response to an ensemble of climate change projections, and separated forecast uncertainty into four different causes: initial conditions, parameters, climate drivers, and process error. We found a strong negative effect of fall–spring maximum temperature, and a positive effect of water‐year precipitation on tree growth. Furthermore, tree vulnerability to climate stress increases with greater competition, with tree size, and at poor sites. Under future climate scenarios, we forecast increment declines of 22%–117%, while the combined effect of climate and size‐related trends results in a 56%–91% decline. Partitioning of forecast uncertainty showed that diameter forecast uncertainty is primarily caused by parameter and initial conditions uncertainty, but increment forecast uncertainty is mostly caused by process error and climate driver uncertainty. This fusion of tree‐ring and forest inventory data lays the foundation for robust ecological forecasting of aboveground biomass and carbon accounting at tree, plot, and regional scales, including iterative improvement of model skill. Great enthusiasm surrounds forest carbon sequestration as a way to offset carbon emissions and address the climate crisis, but ecological complexity contributes to scientific uncertainty about forest responses to climate change. Here, we fused together two important sources of information on tree growth – forest inventory and tree‐ring data – to quantify multiple drivers of Pinus ponderosa tree growth (climate sensitivity, competition, tree size, and site quality), and their interactions. Ecological forecasting approaches indicate that growth will decline by 56%–91% under future climate conditions and allow us to identify the causes of uncertainty surrounding future tree growth.
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ISSN:1354-1013
1365-2486
DOI:10.1111/gcb.16038