Seasonal Rainfall Prediction for the Southeast U.S. Using Sea Surface Temperature Information

Proceedings of the 2011 Georgia Water Resources Conference, April 11, 12, and 13, 2011, Athens, Georgia. This article presents a novel method able to identify and use the most relevant sea surface temperature (SST) information for seasonal rainfall prediction in the Southeast United States (SE US)....

Full description

Bibliographic Details
Main Authors: Chen, Chia-Jeng, Georgakakos, Aristidis P.
Other Authors: Carroll, G. Denise, Georgia Institute of Technology
Format: Conference Object
Language:English
Published: Georgia Institute of Technology 2011
Subjects:
Online Access:http://hdl.handle.net/1853/46241
Description
Summary:Proceedings of the 2011 Georgia Water Resources Conference, April 11, 12, and 13, 2011, Athens, Georgia. This article presents a novel method able to identify and use the most relevant sea surface temperature (SST) information for seasonal rainfall prediction in the Southeast United States (SE US). The method searches for oceanic dipole areas with strong teleconnection relationships with rainfall, and generates seasonal forecasts based on a Bayesian forecasting scheme. The dipoles comprise oceanic areas of various sizes and geographic location, with the difference of the average SST over the poles being the predictor information. Dipole generation is based on teleconnection strength evaluation by the Gerrity Skill Score (GSS). In this application, seasonal rainfall series in the SE US is adopted as the predictand variable. Results show that the strongest predictability exists in winter (December – February). Even at lead times of 3 – 6 months, ensemble forecasts explain more than 50% of the observed rainfall variation. Zonal dipoles in North Atlantic near the Tropic of Cancer, dipoles between North Pacific and Northeast Atlantic, and ENSO-like dipoles are the most statistically significant patterns influencing winter SE US rainfall. Temporal and spatial persistence of SST are identified as oceanic patterns driving corresponding atmospheric circulation modes and affecting rainfall. Skill in other seasons are moderate compared to winter, however useful predictabilities appear in different lead times. On-going work focuses on assessing the value of the forecasts for agriculture and water resources management. Three rainfall stations at Buford dam, West Point Dam, and Montezuma as shown in Figure 1 are used for generating seasonal rainfall series. The monthly average rainfall climatology is also shown indicating that winter rainfall is significant for the ACF water resources. Figure 2 presents ensemble forecast results of winter rainfall with 6 months lead time compared with observations. In the model calibration ...