Mechanistic modeling of climate effects on redistribution and population growth in a community of fish species |
| |
Authors: | Becky Tang Sarah M. Roberts James S. Clark Alan E. Gelfand |
| |
Affiliation: | 1. Department of Mathematics and Statistics, Middlebury College, Middlebury, Vermont, USA;2. Department of Earth, Marine, and Environmental Science, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina, USA;3. Nicholas School of the Environment, Duke University, Durham, North Carolina, USA;4. Department of Statistical Science, Duke University, Durham, North Carolina, USA |
| |
Abstract: | Understanding community responses to climate is critical for anticipating the future impacts of global change. However, despite increased research efforts in this field, models that explicitly include important biological mechanisms are lacking. Quantifying the potential impacts of climate change on species is complicated by the fact that the effects of climate variation may manifest at several points in the biological process. To this end, we extend a dynamic mechanistic model that combines population dynamics, such as species interactions, with species redistribution by allowing climate to affect both processes. We examine their relative contributions in an application to the changing biomass of a community of eight species in the Gulf of Maine using over 30 years of fisheries data from the Northeast Fishery Science Center. Our model suggests that the mechanisms driving biomass trends vary across space, time, and species. Phase space plots demonstrate that failing to account for the dynamic nature of the environmental and biologic system can yield theoretical estimates of population abundances that are not observed in empirical data. The stock assessments used by fisheries managers to set fishing targets and allocate quotas often ignore environmental effects. At the same time, research examining the effects of climate change on fish has largely focused on redistribution. Frameworks that combine multiple biological reactions to climate change are particularly necessary for marine researchers. This work is just one approach to modeling the complexity of natural systems and highlights the need to incorporate multiple and possibly interacting biological processes in future models. |
| |
Keywords: | climate change competition dispersal fisheries ecology food web interaction strength Markov chain Monte Carlo predator–prey |
|
|