The role of belowground competition and plastic biomass allocation in altering plant mass-density relationships
Authored by Volker Grimm, Uta Berger, Yue Lin, Franka Huth
Date Published: 2014
DOI: 10.1111/j.1600-0706.2013.00921.x
Sponsors:
Initiative and Networking Fund of the Helmholtz Association (NRB)
Platforms:
NetLogo
Model Documentation:
ODD
Mathematical description
Model Code URLs:
Model code not found
Abstract
Metabolic scaling theory (MST) predicts a universal scaling law' for
plant mass-density relationships, but empirical observations are more
variable. Possible explanations of this variability include plasticity
in biomass allocation between the above- and belowground compartment and
different modes of competition, which can be asymmetric or symmetric.
Although complex interactions of these factors are likely to occur, so
far the majority of modelling and empirical studies has focussed on
mono-factorial explanations. We here present a generic individual-based
model, which allows exploring the plant mass-density relationship in
realistic settings by representing plasticity of biomass allocation and
different modes of competition in the above- and belowground
compartment. Plants grew according to an ontogenetic growth model
derived from MST. To evaluate the behavior of the simulated plants
related to the allocation patterns and to validate model predictions, we
conducted greenhouse experiments with tree seedlings. The model
reproduced empirical patterns both at the individual and population
level. Without belowground resource limitation, aboveground processes
dominated and the slopes of mass-density relationships followed the
predictions of MST. In contrast, resource limitation led to an increased
allocation of biomass to belowground parts of the plants. The subsequent
dominance of symmetric belowground competition caused significantly
shallower slopes of the mass-density relationship, even though the
growth of individual plants followed MST. We conclude that changes in
biomass allocation induced by belowground resource limitation explain
the deviations from the mass-density relationship predicted by MST.
Taking into account the plasticity of biomass allocation and its linkage
to the above- and belowground competition is critical for fully
representing plant communities, in particular for correctly predicting
their response of carbon storage and sequestration to changing
environmental conditions.
Tags
Light
Populations
Communities
General-model
Symmetry
Asymmetric competition
Allometry
Root competition
Size asymmetry
Tree growth