Abstract
The transformation of a river into a reservoir and the subsequent occupation of the riverbed by a reservoir can impact freshwater ecosystems and their biodiversity. We used the National Lake Assessment (134 reservoirs) and the National Rivers and Streams Assessment (2062 rivers and streams) of the United States Environmental Protection Agency in order to develop empirical characterization factors (CFs; in Potentially Disappeared Fraction of species [PDF]) evaluating the impacts of reservoir occupation on macroinvertebrate richness (number of taxa) at the reservoir, ecoregion and country spatial scales, using a space-for-time substitution. We used analyses of variance, variation partitioning, and multiple regression analysis to explain the role of ecoregion (or regionalization; accounting for spatial variability) and other potentially influential variables (physical, chemical and human), on PDFs. At the United States scale, 28% of macroinvertebrate taxa disappeared during reservoir occupation and PDFs followed a longitudinal gradient across ecoregions, where PDFs were higher in the west. We also observed that high elevation, oligotrophic and large reservoirs had high PDF. This study provides the first empirical macroinvertebrate-based PDFs for reservoir occupation to be used as CFs by LCA practitioners. The results provide strong support for regionalization and a simple empirical model for LCA modelers.
Highlights
Water abstraction, regulation of water flow by dams, and water diversion by channels have benefited human populations worldwide [1,2,3]
Our empirically derived PDFusa and PDFeco showed a loss in macroinvertebrate richness due to reservoir occupation in the United States and this loss followed a longitudinal gradient associated with the ecoregions (Figure 2)
At the United States scale, 28% of macroinvertebrate taxa disappeared in response to river impoundment
Summary
Water abstraction (withdrawal), regulation of water flow by dams (storage reservoirs for drinking water, flood control, and energy production), and water diversion by channels (irrigation and navigation) have benefited human populations worldwide [1,2,3]. Despite clear societal benefits, the use of water is often accompanied by a myriad of environmental impacts [4,5,6,7,8]. The environmental impacts brought about by dams are well documented [9]. Geomorphology, water depth and hydrological regime are notably altered. Temperature and total dissolved solids affect ecosystem productivity [10,11,12,13]. A change in the hydrological regime (lotic into a lentic ecosystem, upstream of the dam) affects several physical and biological processes, as well as organisms’ capacities to thrive and Sustainability 2021, 13, 2701.
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