David Gutzler - US grants

Abstract ATM-9731089 Gutzler, David S. University of New Mexico Title: Observations and Modeling of Large-Scale Controls on Summer Rainfall in Southwest North America The broad goals of the proposal are to characterize interannual summer precipitation anomalies in the southwestern United States in order to guide future prediction effort. Observational data along with the CCM3 model output will be analyzed. A control run of CCM3 with the SST fixed will be examined for realistic monsoon simulation across the southwest USA. If the simulation is not realistic, sensitivity experiments for artificial topographic relief will be conducted. Water being very important over this region, any new insights into the mechanisms that modulate summer rainfall in the southwest USA will have important social benefits.

0083752
Ward

Faculty from the University of Alabama and the University of
New Mexico will coordinate development of a Biocomplexity
research proposal that (1) advances our current, limited
understanding of how droughts are initiated and maintained; and
(2) provides assessments of impacts of drought in river basins in
the contrasting mesic and semi-arid climates of Alabama and
New Mexico. We will develop a new, quantitative understanding
of biological, hydrological and atmospheric interactions that control
initiation, duration, and consequences of drought. Our ultimate
goal is to understand biotic response to drought well enough to
make estimates of climate feedback and contribute to better
predictive climate models. The planning proposal will fund
analyses and integration of relevant data sets from both regions,
travel for faculty exchanges, and full-group workshops to facilitate
preparation of a biocomplexity and other interdisciplinary research
proposals appropriate for this theme.

This is one of 16 Rapid Response (RAPID) projects funded as the result of a Dear Colleague Letter (NSF 11-006) encouraging diagnostic analyses of climate model simulations prepared for the Intergovernmental Panel on Climate Change Fifth Assessment Report (IPCC AR5). Research conducted in these projects is expected to lead to more detailed model intercomparisons, better understanding of robust model behaviors, and better understanding and quantification of uncertainty in future climate simulations.

Analysis conducted in this project examines the veracity and robustness of the climate change simulations for the AR5 as part of the Coupled Model Intercomparison Project version 5 (CMIP5), particularly with respect to projected hydroclimatic changes in the water limited region of southwestern North America. Warming trends are already particularly pronounced in this region in the spring season, which is a critical issue for surface hydrology due to the sensitivity of snowpack to spring warming, and the relative lack of precipitation during this season. Therefore climate change at this time of year has a potentially dramatic effects on snow-fed rivers and on soil moisture during the start of the growing season. The projected hydrologic changes associated with these trends are one of the most pronounced and significant signals that appeared in an earlier generation of climate model simulations prepared for the IPCC Fourth Assessment Report (AR4), so it is important to examine CMIP5 simulations carefully to examine the hydroclimatic processes simulated in current model. The research also examines the simulation of summer rainfall in the region, and in this season simulations used for AR4 were not consistent from one model to another. Thus, the extent to which the new generation of models produces a consistent response of summertime rainfall in the southwest to greenhouse gas increases is considered. Model outputs to be examined include maximum and minimum temperature, focusing on the spring and summer seasons, surface fluxes in the spring and summer seasons, soil moisture, snowfall in mountainous regions in the winter and spring seasons, and pecipitation from winter through summer.

The broader impact of the project lies in its support of the IPCC AR5, which is intended to provide information on climate change and its consequences to decision makers worldwide. The hydroclimate of southwestern North America is of great societal interest given the large population and population growth in the region, as well as the importance of the region for agriculture and the sensitive ecosystems contained within it.