Abstract
Identifying priority zones for river restoration is important for biodiversity conservation and catchment management. However, limited data due to the difficulty of field collection has led to research to better understand the ecological status within a catchment and develop a targeted planning strategy for river restoration. To address this need, coupling hydrological and machine learning models were constructed to identify priority zones for river restoration based on a dataset of aquatic organisms (i.e., algae, macroinvertebrates, and fish) and physicochemical indicators that were collected from 130 sites in September 2014 in the Taizi River, northern China. A process-based model soil and water assessment tool (SWAT) was developed to model the temporal-spatial variations in environmental indicators. A support vector machine (SVM) model was applied to explore the relationships between aquatic organisms and environmental indicators. Biological indices among different hydrological periods were simulated by coupling SWAT and SVM models. Results indicated that aquatic biological indices and physicochemical indicators exhibited apparent temporal and spatial patterns, and those patterns were more evident in the upper reaches compared to the lower reaches. The ecological status of the Taizi River was better in the flood season than that in the dry season. Priority zones were identified for different hydrological seasons by setting the target values for ecological restoration based on biota organisms, and the results suggest that hydrological conditions significantly influenced restoration prioritization over other environmental parameters. Our approach could be applied in other seasonal river ecosystems to provide important preferences for river restoration.
Highlights
The ecological status of rivers is tightly related to human society
The objective of this study is to construct a relationship between aquatic organisms and water physicochemical factors using appropriate models, and to achieve continuous simulation of aquatic organisms on a spatio-temporal scale through a distributed hydrological model
The result indicated that the indices of fish communities (i.e., fish Berger-Parker index (F_BP), fish species richness (F_S)) and algal communities (i.e., algae Berger-Parker index (A_BP), algae species richness (A_S)) were better fitted with the environmental variables when compared with the indicators of macroinvertebrate fauna (i.e., M_BMWP, macroinvertebrate families richness (M_S))
Summary
The ecological status of rivers is tightly related to human society. Human activities referring to industry, agriculture, and construction may affect important ecological functions and processes, such as nutrient cycling and carbon flux in food webs [1,2,3], change hydrological regimes, and lead to habitat degradation. The response of river ecosystems to those human activities varies with temporal and spatial scales, which poses a conundrum for river remediation and flow regulation [4,5]. There is a great interest in understanding how the ecological status of rivers changes with temporal and. Res. Public Health 2018, 15, 2090; doi:10.3390/ijerph15102090 www.mdpi.com/journal/ijerph
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More From: International Journal of Environmental Research and Public Health
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