Resource dynamics and plant growth: A self-assembling model for individuals, populations and communities
Authored by RL Colasanti, R Hunt
Date Published: 1997
DOI: 10.1046/j.1365-2435.1997.00088.x
Sponsors:
United Kingdom Natural Environment Research Council (NERC)
Platforms:
Microsoft Windows
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
1. We describe a new model of plant growth that is general, deterministic, non-stationary and mechanistic in nature. Its purpose is
to investigate the extent to which the morphology and function of the
whole plant can be determined by resource acquisition and utilization on
the part of its components.
2. The model is a two-dimensional section, showing the plant in its
above- and below-ground environments. The whole plant is represented by
a branching structure made up from standard `modules'. The behaviour of
the complete plant is determined exclusively by a rule set that acts
only at the level of the individual module.
3. At the level of the whole plant, the model displays a classic
S-shaped growth curve, plasticity in root-shoot allocation, and foraging
in heterogeneous environments.
4. At the level of the plant population, the model exhibits
self-thinning along a -2/1 self-thinning line. This accords with the
behaviour expected of a two-dimensional system and also adds weight to
the `geometric' interpretation of the -3/2 self-thinning Line commonly
seen in crowded populations of real plants.
5. An imposed `mutation' in one of the modular rules allows us to
produce a modified plant type that displays active foraging. In a set of
simulations involving a model community containing both the modified and
standard plant types, the modified type predominates in resource-rich
environments, and vice versa.
6. The simulations demonstrate the effectiveness of modular rule-based
methods from which whole-plant behaviour can arise as an emergent
property. The model suggests that active foraging carries a cost that
cannot satisfactorily be borne at low levels of resource availability.
It also implies that competition for resources, both above and below
ground is in the form of a `contest' (rather than a `scramble'). The
success of the modular model highlights the primacy of resource
acquisition and utilization in determining the ecological status of the
plant.
Tags
Acquisition
Rule
Soil