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Systems ecology (Rev #10, changes)

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Contents

Idea

Systems ecology is an interdisciplinary field of ecology, taking a holistic approach to the study of ecological systems, especially entire ecosystems. Systems ecology can be seen as an application of general systems theory to ecology. Central to the systems ecology approach is the idea that an ecosystem is a complex system exhibiting emergent properties. Systems ecology focuses on interactions and transactions within and between biological and ecological systems, and is especially concerned with the way the functioning of ecosystems can be influenced by human interventions. It uses and extends concepts from thermodynamics and develops other macroscopic descriptions of complex systems.

Examples

Howard Odum

The ‘Energy Systems Language’ was developed by Howard T. Odum and his colleagues in the 1950s during studies of the tropical forests funded by the United States Atomic Energy Commission. Odum is the founder of ‘systems ecology’:

Sometimes called ‘Energese’, the Energy Systems Language is a diagrammatic language featuring elements like these:

Energy Systems Symbols

His most detailed book on diagrams for systems ecology seems to be this:

  • Howard T. Odum, Systems Ecology: an Introduction, Wiley-Interscience, New York, 1983.

In this book:

  • R. L. Kitching, Systems Ecology: An Introduction to Ecological Modelling, University of Queensland Press, 1983.

the author writes:

Because of its electrical analogy, the Odum system is relatively easy to turn into mathematical equations…. If one is building a model of energy flow then certainly the Odum system should be given serious consideration…

According to the Wikipedia article on Odum, the Energy Systems Language language looks similar to the Systems Modeling Language recently developed by INCOSE, an international Systems Engineering body.

Climate change impact on forests

Dr. Andreas Fischlin is a Systems Ecology scientist who has contributed to IPCC reports. His work is mainly in modelling ecosystems, in collaboration with field researchers. He focuses on the impact of climate change on ecosystems, especially forest.

There are many types of model. A commonly used type involves ‘patch dynamics’. For example, an old tree dies, leaving a gap, and seedlings compete for light and nutrients. Seedlings vary: some tolerate shadows, others need more light, and so on. The model tracks individual trees and includes environmental variables such as precipitation which shape the competition. Such models are caricatures or cartoons, and do not attempt to match reality, but can nonetheless capture crucial aspects of a real forest. Different models suit different purposes: one would be used for predicting climate change impact, another for deciding how to best fertilise a forest.

These are some of the best models in ecology. They can predict what kind of natural forest you will find at a particular location, given information about the climate and soil. As well as predicting what we find today, they can also match what happened at the end of the last ice age, as determined from pollen data. This gives some confidence that they can predict what kind of forests we will have in the future.

Food webs

An interesting question in systems ecology is: which factors make a food web stable or unstable? For decades there has been an intense debate on this question, beginning with quite crude models and moving to ever more realistic ones, and also featuring ever more careful experiments. An excellent review article, featuring a large bibliography, is:

Many consider the father of food-web ecology to be Charles Elton, who in the 1920s noted the ‘pyramid of numbers’ and other basic features of food webs. Elton noted that some simple two-species predator-prey models are unstable and argued that complex food webs were more stable. In 1942, R. L. Lindeman focused attention on the flow of energy through food webs. In the early 1970s, R. M. May showed that in some models, food webs became less stable as the number and strength of species interactions increased:

  • R. M. May, Stability and Complexity of Model Ecosystems, 2nd edition, Princeton U. Press, Princeton, New Jersey, 1974.

This led to an outburst of work seeking to show that May’s results were based on oversimplifications, e.g. assuming that any given species has an equal probability of interacting with any other. In the later 1970s, J. E. Cohen began investigating the topology of food webs:

  • J. E. Cohen, Food Webs and Niche Space, Princeton U. Press, Princeton, New Jersey, 1978.

Here is a more recent article in this line of work:

  • Phillip P. A. Staniczenko, Owen T. Lewis, Nick S. Jones and Felix Reed-Tsochas, Structural dynamics and robustness of food webs, Ecology Letters 13 (2010), 891-899.

Abstract: Food web structure plays an important role when determining robustness to cascading secondary extinctions. However, existing food web models do not take into account likely changes in trophic interactions (‘rewiring’) following species loss. We investigated structural dynamics in 12 empirically documented food webs by simulating primary species loss using three realistic removal criteria, and measured robustness in terms of subsequent secondary extinctions. In our model, novel trophic interactions can be established between predators and food items not previously consumed following the loss of competing predator species. By considering the increase in robustness conferred through rewiring, we identify a new category of species–overlap species–which promote robustness as shown by comparing simulations incorporating structural dynamics to those with static topologies. The fraction of overlap species in a food web is highly correlated with this increase in robustness; whereas species richness and connectance are uncorrelated with increased robustness. Our findings underline the importance of compensatory mechanisms that may buffer ecosystems against environmental change, and highlight the likely role of particular species that are expected to facilitate this buffering.

Felix Reed-Tsochas is the head of the Complex Agent-Based Dynamic Networks (or ‘CABDyn’) group at the University of Oxford:

References

Here is a good place to start:

This is a collection of classic papers from 1963 to 1979:

  • H. H. Shugart and R. V. O’Neill, Systems Ecology, Dowden, Hutchinson and Ross, Stroudsburg, Pennsylvania, 1979.

Among other things it includes some classic papers on the stability of food webs:

  • M. R. Gardner and W. R. Ashby, Connectance of large dynamic (cybernetic) systems: critical values for stability, Nature 228 (1970), 784.

  • M. L. Rosenzweig, Paradox of enrichment: destabilization of exploitation ecosystems in ecological time, Science 171 (1971), 385-387.

  • R. M. May, Will a large complex system be stable?, Nature 238 (1972), 413-414.

  • D. L. Angelides, Stability and connectance in food webs, Ecology 56 (1975), 238-243.

Odum’s book:

  • Howard T. Odum, Systems Ecology: an Introduction, Wiley-Interscience, New York, 1983.

is a classic reference. The account of Fischlin’s work is based on this interview. Our section on Odum is taken from

  • John Baez and Jacob Biamonte, Diagrams.

For a broad overview of biological networks, see this collection of papers:

  • Francois Képès, ed. Biological Networks, World Scientific, Singapore, 2007.

This contains Louis-Félix Bersier’s A history of the study of ecological networks, mentioned above, but also many other interesting papers.