Living within dynamic social-ecological freshwater systems: System parameters and the role of ecological engineering

• Published in: Ecological engineering Vol. 37; no. 11; pp. 1661 - 1672
• Main Authors: Roy, Eric D., Martin, Jay F., Irwin, Elena G., Conroy, Joseph D., Culver, David A.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.11.2011
• Subjects: Cultural eutrophication; Ecosystem stability; Invasive species; Lake Erie; Lake management; Phosphorus; Social-ecological landscape; Lake Erie; Phosphorus; Invasive species; Social-ecological landscape; Cultural eutrophication; Lake management
• ISSN: 0925-8574; 1872-6992
• DOI: 10.1016/j.ecoleng.2011.06.044

The objective of ecological engineering is to design sustainable ecosystems that integrate human communities and their natural environment for the benefit of both. In this paper, we illustrate how social-ecological modeling can be used as a tool to clarify this objective at a landscape scale for freshwater systems. Coupled social-ecological systems (SESs) are open, dynamic systems subject to both ecological and socioeconomic perturbations. Here we demonstrate the interactive effects of social and technological uncertainties on SES dynamics over time. Additionally, we integrate research on ecosystem stability, social-ecological modeling, and ecological engineering to offer guidance for research at the human-environment interface. Based on a case study of Lake Erie's Sandusky watershed, we use an integrated human-biophysical model to investigate the influence of two parameters on SES dynamics: (1) regional societal preferences that impact watershed management and (2) technological innovation that alters agricultural nutrient efficiency. Our results illustrate ways in which SES dynamics and optimum management strategies depend on societal preferences within the region, indicating a key area of uncertainty for future investigation. As guidance for SES restoration, our model results also illustrate the conditions under which technological change that increases nutrient efficiency on farms can and cannot create a win-win, or increase both human welfare and SES resistance to eutrophication simultaneously. Using these results, we elucidate the value of ecological engineering and offer guidance for assessments of ecological engineering projects using social-ecological modeling.