Implications of Vegetation Dynamics for Semi-Arid Hydrology: A Basis for Predicting Climate Impacts on Water Resources
Duke University, Durham NC
Investigators
Abstract
Implications of Vegetation Dynamics for Semi-Arid Hydrology: A Basis for Predicting Climate Impacts on Water Resources PI: John D. Albertson, Duke University Collaborator: Nicola Montaldo, University of Cagliari, Italy Abstract: This project addresses the coupled eco-hydrologic dynamics of semi-arid Mediterranean watersheds, where the surface drinking-water reservoirs depend almost exclusively on overland flow in the rainy season and where the vegetation growth is water limited. The motivation centers on the observed and projected decreases in winter rainfall, stemming from shifts in large-scale atmospheric circulation patterns. Presently, the ability to predict future hydrologic behavior of these systems is limited by gaps in understanding of how changes in the vegetation cover interact with precipitation dynamics to control the hydrological response. The proposed research will test a set of five focused hypotheses in a Sardinian study basin that is already instrumented and broadly representative of semi-arid Mediterranean watersheds. This project builds on experimental and modeling studies that the PI and Italian collaborator have been conducting for the past several years on Sardinia, the second largest island in the Mediterranean. This project would add overland flow experiments to capture the effect of variable grass cover and rainfall intensity on infiltration and runoff generation. Analysis will be conducted over three overlapping time periods, representing: 1) the intensive field experiment record (~ 5+ years), 2) the satellite record (~ 20+ years), and 3) the streamflow and precipitation record (~ 80 years). Analysis will include possible tradeoffs between infiltration and evapotranspiration. Intellectual Merit: This project is designed to reveal how change and variability in seasonal precipitation patterns excite vegetation dynamics and how these changes in turn impact the hydrological budget of semi-arid watersheds. The tools developed will enable rigorous prediction of the response of eco-hydrological systems to climate forcing. The connection of the results to the large-scale circulation indices is expected to lead to improved predictability at the seasonal time scale. Furthermore, the broad prevalence of Mediterranean climates (e.g. California) simplifies the transferability of the approach and findings. Broader Impacts: The results of the proposed activity will provide direct support for planning water resources needs in the face of systematic changes in Mediterranean precipitation regimes. The undergraduate and Ph.D. students trained on this project will experience broad and meaningful interdisciplinary research experience, including collaborative periods abroad. Preliminary efforts were funded by Duke start-up support to the PI. Duke will provide funding (Pratt Fellowship) for summer support of the undergraduate student researcher.
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