Your search keyword '"Goel, Nikunj"' showing total 2 results

1. The Mismatch between Range and Niche Limits due to Source-Sink Dynamics Can Be Greater than Species Mean Dispersal Distance.

Author

Goel, Nikunj and Keitt, Timothy H.

Subjects

*SPECIES distribution, *SPECIES, *CLIMATE change, *TWO-dimensional models, *PER capita, *CURVATURE, *HABITATS

Abstract

Species distribution models assume that at broad spatial scales, environmental conditions determine species ranges and, as such, source-sink dynamics can be ignored. A rationale behind this assumption is that source-sink dynamics manifest at length scales comparable to species mean dispersal distance, which is much smaller than length scales of species distribution and variation in climate. Using a two-dimensional reaction-diffusion model, we show that species can use sink habitats near the niche limit as stepping-stones to occupy sink habitats much further than the mean dispersal distance, thereby extending the distribution far beyond the environmental niche limit. This mismatch between range and niche limits is mediated by the shape (local curvature) of the niche limit. These curvature effects may be significant for a highly dispersive species with low per capita growth rate sensitivity to changes in the environment. These findings underscore the potential importance of stepping-stone dispersal in determining range limits. [ABSTRACT FROM AUTHOR]

Published

2022

2. Scale invariance in the spatial-dynamics of biological invasions.

Author

Liebhold, Andrew M., Keitt, Timothy H., Goel, Nikunj, and Bertelsmeier, Cleo

Subjects

BIOLOGICAL invasions, MICROSPACECRAFT, DEMOGRAPHY, HABITATS

Abstract

Despite the enormous negative consequences of biological invasions, we have a limited understanding of how spatial demography during invasions creates population patterns observed at different spatial scales. Early stages of invasions, arrival and establishment, are considered distinct from the later stage of spread, but the processes of population growth and dispersal underlie all invasion phases. Here, we argue that the spread of invading species, to a first approximation, exhibits scale invariant spatial-dynamic patterns that transcend multiple spatial scales. Dispersal from a source population creates smaller satellite colonies, which in turn act as sources for secondary invasions; the scale invariant pattern of coalescing colonies can be seen at multiple scales. This self-similar pattern is referred to as "stratified diffusion" at landscape scales and the "bridgehead effect" at the global scale. The extent to which invasions exhibit such scale-invariant spatial dynamics may be limited by the form of the organisms' dispersal kernel and by the connectivity of the habitat. Recognition of this self-similar pattern suggests that certain concepts for understanding and managing invasions might be widely transferable across spatial scales. [ABSTRACT FROM AUTHOR]

Published

2020