Using a (slightly) more realistic model resolves the perfect mixing paradox

In a recent paper published in Ecosphere, their authors suggest that extending the logistic growth model in its usual r−K parameterization to a multi-patch environment results in undesirable properties, that were referred to as the “perfect mixing paradox”. ∗[email protected] (corresponding author) †[email protected] 1 ar X iv :1 70 3. 02 96 2v 1 [ qbi o. PE ] 8 M ar 2 01 7 This led the authors to recommend using the Verhulst r − α parameterization of the logistic model instead and abandoning the term “carrying capacity” in the context of population dynamics. In this study we show that the use of the logistic equation in its traditional r −K parameterization is appropriate for representing the dynamics of populations in a simple spatial context with passive migration among patches. Furthermore, we show that the conclusions of the mentioned paper depend on the specific functional form for migration rates used for their analyses. In addition, we suggest that their specific migration model was not the best choice since biologically realistic options exist. Moreover, these alternatives require the same number of parameters. The model we present here is free of the paradoxical behaviors presented previously. This allows us to conclude that the logistic growth in its usual r−K parameterization is useful in a spatial context if extended appropriately to a multi-patch scenario and consequently there are no reasons to abandon the concept of carrying capacity. Ecologists should pay great attention when using models in scenarios that are more complex or just different from the ones for which the models were created. Keywords— Logistic model, migration rate, patch dynamics, space.