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Intermediate-complexity models for landscape effects on fish in river networks
Citation:
Rashleigh, B., J. Ebersole, A. Brookes, M. Snyder, B. Waller, J. Massie, AND G. Boxall. Intermediate-complexity models for landscape effects on fish in river networks. International Society for Ecological Modelling, Vienna, N/A, AUSTRIA, October 01 - 04, 2019.
Impact/Purpose:
This work provides set of suggested approaches for the modeling of fish in stream and river networks with intermediate spatial scale and computational complexity, which includes most of the key factors affects fish communities yet includes simplifying assumptions to make the approach more accessible and transferrable. Several new technologies and data sets facilitate modeling of riverine fishes, to better understand landscape effects, and the response of fish communities to alternative planning and management scenarios.
Description:
Fish communities in river networks provide significant ecosystem services that will likely decline under future land use, human water demand, and climate variability. Modeling can be used to assess the consequences to multiple populations of one or more fish species from multiple stressors across a river network. We propose a modeling approach that is of intermediate scale and complexity. The model is spatially-explicit and age-structured, with three components: habitat suitability; population dynamics, including species interactions; and movement across a spatial network. Although this model is simple, it can form the basis of fisheries assessments and may be incorporated into an integrated modeling system for watershed management and prediction. The approach provides a heuristic tool for identifying critical data gaps in our understanding of watershed-scale fish-habitat relationships, particularly as these may be influenced by species behaviors and interactions. Initial results provide testable hypotheses regarding species distributions and projected fish population responses to environmental change, water consumption, species invasions, and landuse effects on water temperature.