H11I-1461
Large-scale Agroecosytem’s Resiliency to Extreme Hydrometeorological and Climate Extreme Events in the Missouri River Basin
Monday, 14 December 2015
Poster Hall (Moscone South)
Francisco Munoz-Arriola1, Katherine Smith1, Gerald Corzo2 and Juan Chacon2, (1)University of Nebraska Lincoln, Lincoln, NE, United States, (2)UNESCO-IHE� Institute for Water Education, HYDROINFORMATICS, Delft, Netherlands
Abstract:
A major challenge for water, energy and food security relies on the capability of agroecosyststems and ecosystems to adapt to a changing climate and land use changes. The interdependency of these forcings, understood through our ability to monitor and model processes across scales, indicate the “depth” of their impact on agroecosystems and ecosystems, and consequently our ability to predict the system’s ability to return to a “normal” state. We are particularly interested in explore two questions: (1) how hydrometeorological and climate extreme events (HCEs) affect sub-seasonal to interannual changes in evapotranspiration and soil moisture? And (2) how agroecosystems recover from the effect of such events. To address those questions we use the land surface hydrologic Variable Infiltration Capacity (VIC) model and the Moderate Resolution Imaging Spectrometer-Leaf Area Index (MODIS-LAI) over two time spans (1950-2013 using a seasonal fixed LAI cycle) and 2001-2013 (an 8-day MODIS-LAI). VIC is forced by daily/16th degree resolution precipitation, minimum and maximum temperature, and wind speed. In this large-scale experiment, resiliency is defined by the capacity of a particular agroecosystem, represented by a grid cell’s ET, SM, and LAI to return to a historical average. This broad, yet simplistic definition will contribute to identify the possible components and their scales involved in agroecosystems and ecosystems capacity to adapt to the incidence of HCEs and technologies used to intensify agriculture and diversify their use for food and energy production. Preliminary results show that dynamical changes in land use, tracked by MODIS data, require larger time spans to address properly the influence of technologic improvements in crop production as well as the competition for land for biofuel vs. food production. On the other hand, fixed seasonal changes in land use allow us just to identify hydrologic changes mainly due to climate variability.