Exploring the effect of drought extent and interval on the Florida snail kite: interplay between spatial and temporal scales

Authored by Donald L DeAngelis, WM Mooij, RE Bennetts, WM Kitchens

Date Published: 2002

DOI: 10.1016/s0304-3800(01)00512-9

Sponsors: US Fish and Wildlife Service National Park Service United States Army Corps of Engineers South Florida Water Management District St. Johns River Water Management District United-States Geological Survey Biological Resources Division Netherlands Institute of Ecology

Platforms: No platforms listed

Model Documentation: Other Narrative Mathematical description

Model Code URLs: Model code not found

Abstract

The paper aims at exploring the viability of the Florida snail kite population under various drought regimes in its wetland habitat. The population dynamics of snail kites are strongly linked with the hydrology of the system due to the dependence of this bird species on one exclusive prey species. the apple snail, which is negatively affected by a drying out of habitat. Based on empirical evidence, it has been hypothesised that the viability of the snail kite population critically depends not only on the time interval between droughts, but also on the spatial extent of these droughts. A system wide drought is likely to result in reduced reproduction and increased mortality, whereas the birds can respond to local droughts by moving to sites where conditions are still favourable. This paper explores the implications of this hypothesis by means of a spatially-explicit individual-based model. The specific aim of the model is to study in a factorial design the dynamics of the kite population in relation to two scale parameters, the temporal interval between droughts and the spatial correlation between droughts. In the model high drought frequencies led to reduced numbers of kites. Also, habitat degradation due to prolonged periods of inundation led to lower predicted numbers of kites. Another main result was that when the spatial correlation between droughts was low, the model showed little variability in the predicted numbers of kites. But when droughts occurred mostly on a system wide level, environmental stochasticity strongly increased the stochasticity in kite numbers and in the worst case the viability of the kite population was seriously threatened. (C) 2002 Elsevier Science B.V. All rights reserved.

Tags

models Conservation ecology pattern Dispersal Population-dynamics