Evaluating climate change induced water stress: A case study of the Lower Cape Fear basin, NC

With the possibility of future fresh water shortages increasing, a methodology that incorporates climatic and anthropogenic factors is needed. This research estimates future water availability in the Lower Cape Fear basin using changes in climate, land use, and population growth. The USGS Thornthwaite monthly water balance model is used with estimates of climate change and land use change parameters to assess future water resources based on predicted monthly fluxes of the water balance. The southern United States is a rapidly growing region. Trends present in the population data are used to produce future estimates of population for the basin. Precipitation and temperature estimates based on Intergovernmental Panel on Climate Change (IPCC) predictions and current climatology are inputs to the model. Projected increases in impervious surface cover due to population growth and urbanization are incorporated through the model runoff factor. Water stress indicators are used to categorize the sub-watersheds as water rich, water stressed, or water scarce. Scenarios incorporating regional predictions of climate change indicate a decrease in summer soil moisture minima and increases in summer water deficits. Ensemble runs indicate a shift toward water stress in the Lower Cape Fear River basin, due to a warming climate as well as increased demand. While climate change has a significant impact on water resources, population growth was found to have the most substantial impact. The methods and findings have application to water managers at local and regional levels. (C) 2013 Elsevier Ltd. All rights reserved.