Annual River Discharge in Southeastern Australia Related to El-Nino Southern Oscillation Forecasts of Sea-Surface Temperatures

Publication Type  Journal Article
Year of Publication  1993
Authors  Simpson, H. J.; Cane, M. A.; Herczeg, A. L.; Zebiak, S. E.; Simpson, J. H.
Journal Title  Water Resources Research
Volume  29
Issue  11
Pages  3671-3680
Journal Date  Nov
ISBN Number  0043-1397
Accession Number  ISI:A1993MF77000007
Key Words  rainfall; variability; murray; region; circulation; evaporation; anomalies; salinity; winter
Abstract  

Annual natural discharge (Q) of the River Murray and its most extensive tributary, the Darling River system, is often inversely related to sea surface temperature (SST) anomalies in the eastern tropical Pacific Ocean. These SST variations are components of a planetary-scale phenomenon referred to as El Nino-Southern Oscillation (ENSO). Darling and Murray river historical values of Q indicate that annual surface runoff from regions dominated by subtropical summer monsoon precipitation and annual surface runoff primarily responding to temperate winter storms are both strongly influenced by ENSO cycles. Forecasting, approximately 1 year in advance, of ENSO-related SST from geophysical model calculations thus provides a mechanism for estimating probabilities of annual river discharge amount. Contingency tables relating annual Q to SST, based on combining observed data for 95 years and forecast SST over a period of 15 years, provide probabilities of expected annual Q as a function of forecast SST. The SST of the eastern tropical Pacific was successfully forecast to be appreciably warmer than long-term mean conditions for much of the year beginning in mid 1991. Precipitation data through 1991 indicated that annual natural Q for the Darling River was probably substantially below the mean. However, winter precipitation in higher-runoff portions of the Murray Basin was above average during this El Nino episode, contrary to the trend for most such events over the past century.

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URL  <Go to ISI>://A1993MF77000007