Natural length scales of ecological systems: Applications at community and ecosystem levels
Johnson, CR (2009) Natural length scales of ecological systems: Applications at community and ecosystem levels. Ecology and Society, 14 (1). ISSN 1708-3087
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Official URL: http://www.ecologyandsociety.org/vol14/iss1/art7/
The characteristic, or natural, length scales of a spatially dynamic ecological landscape are
the spatial scales at which the deterministic trends in the dynamic are most sharply in focus. Given recent
development of techniques to determine the characteristic length scales (CLSs) of real ecological systems,
I explore the potential for using CLSs to address three important and vexing issues in applied ecology, viz.
(i) determining the optimum scales to monitor ecological systems, (ii) interpreting change in ecological
communities, and (iii) ascertaining connectivity between species in complex ecologies. In summarizing
the concept of characteristic length scales as system-level scaling thresholds, I emphasize that the primary
CLS is, by definition, the optimum scale at which to monitor a system if the objective is to observe its
deterministic dynamics at a system level. Using several different spatially explicit individual-based models,
I then explore predictions of the underlying theory of CLSs in the context of interpreting change and
ascertaining connectivity among species in ecological systems. Analysis of these models support predictions
that systems with strongly fluctuating community structure, but an otherwise stable long-term dynamic
defined by a stationary attractor, indicate an invariant length scale irrespective of community structure at
the time of analysis, and irrespective of the species analyzed. In contrast, if changes in the underlying
dynamic are forcibly induced, the shift in dynamics is reflected by a change in the primary length scale.
Thus, consideration of the magnitude of the CLS through time enables distinguishing between circumstances
where there are temporal changes in community structure but not in the long-term dynamic, from that
where changes in community structure reflect some kind of fundamental shift in dynamics. In this context,
CLSs emerge as a diagnostic tool to identify phase shifts to alternative stable states associated with loss of
resilience in ecological systems and thus provide a means to interpret change in community composition.
By extension, comparison of the CLSs of ostensibly similar communities at different points in space can
reveal whether they experience similar underlying dynamics. Analysis of these models also reveals that
species in the same community whose dynamics are largely independent indicate different length scales.
These examples demonstrate the potential to apply CLSs in a decision-support role in determining scales
for monitoring, interpreting whether change in community structure reflects a shift in underlying dynamics
and therefore may warrant management intervention, and determining connectivities among species in
complex ecological systems.
|Additional Information:||© 2009 CR Johnson|
|Keywords:||attractor reconstruction; characteristic length scale; community change; connectivity;
monitoring; natural length scale; scaling threshold|
|Deposited By:||Ms F Walsh|
|Deposited On:||04 Mar 2009 11:25|
|Last Modified:||04 Mar 2009 11:25|
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