PICTURE PLACEHOLtttDER PICTURE PLACEHOLDER LOGO PICTURE PLACEHOLDER References 1. Jin, X., and V. Sridhar, Impact of climate change on hydrology and water resources in the Boise and Spokane River Basins, Journal of the American Water Resources Association, accepted under revision Dec Williams, J.R., C.A. Jones, J.R. Kiniry and D.A. Spanel The EPIC crop growth model. Trans ASAE 32(2): Gerik, T.J., W.L. Harman, J.R. Williams, L. Francis, J. Greiner, M. Magre, A. Meinardus, and E. Steglich Researcher's Guide: WinEPIC model, version 3.0. Blackland Research and Extension Center, Temple, Texas. 4. Wilson, L. T., Y. Yang, P. Lu, J. Wang, J.W. Nielsen-Gammon, N. Smith, and C.J. Fernandez Integrated Agricultural Information and Management System(iAIMS):World Climatic Data. August Yang, Y., L.T. Wilson, and J. Wang Development of an Automated Climatic Data Scraping, Filtering and Display System. Computers and Electronics in Agriculture 71: Results and Conclusions 1. Introduction Climate change is expected to alter the timing, duration, and quantity of natural precipitation As temperatures increase, precipitation becomes more variable and follows a decreasing trend Changes in precipitation will impact the decisions made by agricultural producers We examine producer incentives to grow different crops and whether they will produce those crops with or without irrigation We focus on the Western Snake River Basin in Idaho Ada, Canyon, Elmore Counties Forage hay is the top commodity produced in all three counties (growing dairy industry) Wheat for grain, barley and sugar-beets are also commonly produced Due to the drier climate conditions in the three counties, only about 10% of the land harvested for each crop is rain-fed 2.Objective Estimate the distribution of yield and revenue for field crops using down-scaled climate projection data from Step 1: Examine rain-fed crops produced in the study region: Alfalfa, Barley, Spring Wheat, Winter Wheat Step 2: Examine irrigated crops produced in the study region, compare with rain-fed Evaluate changes in cropping choices over time based on economic criteria We assume the producers are risk-averse and they update their expectations about a seasonal precipitation based on historical observation (with a moving average) We compare the mean and variance of yield for crops and assess which crop(s) stochastically dominate one another with changing conditions Stochastic dominance examines the trade-off between mean and variance A crop with a higher mean may have a greater variance, so growing that crop entails greater risk (and a greater reward) than growing other crops We estimate whether that mean-variance trade-off changes among the crops considered with changing precipitation 3. Climate Model Climate projection data for the Snake River Basin made available to us through the Idaho EPScoR office Climate predictions made by adding a spatially corresponding temperature factor to the observed monthly mean temperature and by multiplying a spatially corresponding precipitation factor to the observed monthly mean precipitation How will Idaho's Agricultural Producers Adapt to Changing Precipitation Patterns? Evidence from an Integrated Hydrologic-Economic Model Gretchen L. Beebe, Graduate Student, Boise State University Professor Kelly M. Coburn, Department of Economics, Boise State University Professor Alejandro N.Flores,Department of Geosciences, Boise State University The authors gratefully acknowledge support by the Idaho EPSCoR Program and the National Science Foundation under award EPS Figure 2. Properties of Projected Climate Data for Ada County Figure 3. Figure Crop Model Texas AgriLife Research and Extension Center’s EPIC model was used to simulate crop yields in response to the climate projection data Each simulation was calibrated to fit historical yield values Soil input reflects common soil parameter values for southwest Idaho Planting and harvesting dates reflect average planting and harvesting dates in Idaho for each crop Alfalfa harvested 4 times per year Barley, Spring Wheat, Winter Wheat harvested one time per year Other management practices (fertilizing, plowing, etc.) set to default and generated by EPIC program We are not as concerned with the fine-tuning of our crop model as we are in piecing together the crop model and it’s economic impact, thus producing an integrated hydro-economic model that reflects the adaptation of agricultural producers to changing conditions of risk over time 5. Results and Conclusions In general yields and revenue/acre increased Ambiguities may be due to variability taking effect until later in the time frame (after 2040) Alfalfa becomes first-order stochastically dominant over all other crops as time progresses in all three counties Although alfalfa shows the greatest variability and therefore holds the most risk, it is the dominant crop choice moving forward despite the inherent risk. Figure 2. Figure Calibration of Generated Yield (for years ) to Observed Yield (for all years available) Figure 5. Figure 6. Figure 7. Figure Future Work Examine alfalfa, barley, spring wheat and winter wheat under irrigated conditions, compare with rain-fed crop models Consider more crops common to southwestern Idaho and more counties within the Snake River Plain Take farmer’s decisions on crop choice and whether crops should be irrigated or rain-fed as input into the model Update the model after each harvest with the farmer’s new input for the next growing season