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Climate‐related variation in mortality and recruitment determine regional forest‐type distributions
Author(s) -
Vanderwel Mark C.,
Lyutsarev Vassily S.,
Purves Drew W.
Publication year - 2013
Publication title -
global ecology and biogeography
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.164
H-Index - 152
eISSN - 1466-8238
pISSN - 1466-822X
DOI - 10.1111/geb.12081
Subject(s) - forest dynamics , climate change , taiga , ecology , competition (biology) , temperate rainforest , population , temperate climate , temperate forest , boreal , environmental science , geography , physical geography , biology , ecosystem , demography , sociology
Aim The geographic distributions of different forest types are expected to shift in the future under altered climatic conditions. At present, the nature, magnitude and timing of these shifts are uncertain because we lack a quantitative understanding of how forest distributions emerge from climate‐ and competition‐related variation in underlying demographic processes. Forest dynamics result primarily from the manner in which the physical environment and competition for limiting resources affect tree growth, mortality and recruitment. We sought to uncover the relative importance of these processes in controlling the geographic limits of different forest types. Location E astern USA . Methods We parameterized a climate‐dependent forest dynamics model with extensive observations of tree growth, mortality and recruitment from forest inventory data. We then implemented the resulting demographic models in simulations of joint population dynamics for seven plant functional types ( PFTs ) across the region. By removing various climate effects in a series of simulation experiments, we assessed the importance of climate‐dependent demography and competition in limiting forest distributions. Results Distributions that emerged from simulated population dynamics approximated the current distributions for all seven PFT s well and captured several known patterns of succession. Temperature‐related increases in mortality determined the southern boundaries of three out of four boreal and northern temperate PFT s, whereas temperature‐related decreases in recruitment controlled the northern limit of all three southern temperate PFT s. Changes in growth rates and competitor performance had only minor effects on the distribution limits of most PFTs . Main conclusions Our results imply that dynamic global vegetation models, which are widely used to predict future vegetation distributions under climate change, should seek to more appropriately capture the observed climate sensitivity of mortality and recruitment. Understanding the mechanisms controlling forest distributions will enable better predictions of their future responses to climate change.

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