Multidimensional trait space informed by a mechanistic model of tree growth and carbon allocation
Authored by Jeremy W Lichstein, Jarrett Barber, Kiona Ogle, Michael Fell
Date Published: 2018
DOI: 10.1002/ecs2.2060
Sponsors:
United States National Science Foundation (NSF)
Platforms:
R
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Plant functional traits research has revealed many interesting and
important patterns among morphological, physiological, and life-history
traits and the environment. These are exemplified in trade-offs between
groups of traits such as those embodied in the leaf and wood economics
spectra. Inferences from empirical studies are often constrained by the
correlative nature of the analyses, availability of trait data, and a
focus on easily measured traits. However, empirical studies have been
fundamental to modeling endeavors aiming to enhance our understanding of
how functional traits scale up to affect, for example, community
dynamics and ecosystem productivity. Here, we take a complementary
approach utilizing an individual-based model of tree growth and
mortality (the allometrically constrained growth and carbon allocation
[ACGCA] model) to investigate the theoretical trait space (TTS) of
North American trees. The model includes 32 parameters representing
allometric, physiological, and anatomical traits, some overlapping leaf
and wood economics spectra traits. Using a Bayesian approach, we fit the
ACGCA model to individual tree heights and diameters from the USFS
Forest Inventory and Analysis (FIA) dataset, with further constraints by
literature-based priors. Fitting the model to 1.3 million FIA
recordsaggregated across individuals, species, and sitesproduced a
posterior distribution of traits leading to realistic growth. We
explored this multidimensional posterior distribution (the TTS) to
evaluate trait-trait relationships emerging from the ACGCA model, and
compare these against empirical patterns reported in the literature.
Only three notable bivariate correlations, among 496 possible trait
pairs, were contained in the TTS. However, stepwise regressions
uncovered a complicated structure; only a subset of traitsrelated to
photosynthesis (e.g., radiation-use efficiency and maintenance
respiration)exhibited strong multivariate trade-offs with each other,
while half of the traitsmostly related to allometries and construction
costsvaried independently of other traits. Interestingly, specific leaf
area was related to several rarely measured root traits. The trade-offs
contained in the TTS generally reflect mass-balance (related to carbon
allocation) and engineering (mostly related to allometries) trade-offs
represented in the ACGCA model and point to potentially important traits
that are under-explored in field studies (e.g., root traits and branch
senescence rates).
Tags
Individual-based model
Productivity
ecology
Area
Photosynthesis
Plant traits
Leaf economics spectrum
Wood
Stomatal conductance
Plant functional traits
Forest inventory and analysis (fia)
Markov
chain monte carlo
North american trees
Trait
space
Trait trade-offs
Tree growth model
Radiation use efficiency
Rain-forest trees