INDIVIDUAL-BASED MODELS AND THE MANAGEMENT OF SHOREBIRD POPULATIONS
Article first published online: 5 MAR 2008
©2008 Blackwell Publishing, Inc.
Natural Resource Modeling
Volume 21, Issue 1, pages 3–71, Spring 2008
How to Cite
GOSS-CUSTARD, J. D. and STILLMAN, R. A. (2008), INDIVIDUAL-BASED MODELS AND THE MANAGEMENT OF SHOREBIRD POPULATIONS. Natural Resource Modeling, 21: 3–71. doi: 10.1111/j.1939-7445.2008.00006.x
- Issue published online: 5 MAR 2008
- Article first published online: 5 MAR 2008
- Received by the editors on 9th September 2005. Accepted 26th September 2005.
- wading birds;
- habitat loss;
- Spartina and birds;
- mitigating measures;
- sea-level rise
Abstract Individual-based models (IBMs) predict how animal populations will be affected by changes in their environment by modeling the responses of fitness-maximizing individuals to environmental change and by calculating how their aggregate responses change the average fitness of individuals and thus the demographic rates, and therefore size of the population. This paper describes how the need to develop a new approach to make such predictions was identified in the mid-1970s following work done to predict the effect of building a freshwater reservoir on part of the intertidal feeding areas of the shorebirds Charadrii that overwinter on the Wash, a large embayment on the east coast of England. The paper describes how the approach was developed and tested over 20 years (1976–1995) on a population of European oystercatchers Haematopus ostralegus eating mussels Mytilus edulis on the Exe estuary in Devon, England.
The paper goes on to describe how individual-based modeling has been applied over the last 10 years to a wide range of environmental issues and to many species of shorebirds and wildfowl in a number of European countries. Although it took 20 years to develop the approach for 1 bird species on 1 estuary, ways have been found by which it can now be applied quite rapidly to a wide range of species, at spatial scales ranging from 1 estuary to the whole continent of Europe. This can now be done within the time period typically allotted to environmental impact assessments involving coastal bird populations in Europe.
The models are being used routinely to predict the impact on the fitness of coastal shorebirds and wildfowl of habitat loss from (i) development, such as building a port over intertidal flats; (ii) disturbance from people, raptors, and aircraft; (iii) harvesting shellfish; and (iv) climate change and any associated rise in sea level. The model has also been used to evaluate the probable effectiveness of mitigation measures aimed at ameliorating the impact of such environmental changes on the birds. The first steps are now being taken to extend the approach to diving sea ducks and farmland birds during the nonbreeding season.
The models have been successful in predicting the observed behavior and mortality rates in winter of shorebirds on a number of European estuaries, and some of the most important of these tests are described. These successful tests of model predictions raise confidence that the model can be used to advise policy makers concerned with the management of the coast and its important bird populations.