Influence of the Antarctic Circumpolar Wave on Australian Precipitation from 1958 to 1997

Year-to-year changes are found in Australian precipitation (APP) covarying with those in sea surface temperature (SST) and troposphere moisture flux (MF) over the three oceans surrounding Australia for 40 yr from 1958 to 1997. Australia’s wet (dry) years are associated with warm (cool) SST anomalies...

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Bibliographic Details
Published inJournal of climate Vol. 13; no. 13; pp. 2125 - 2141
Main Author White, Warren B.
Format Journal Article
LanguageEnglish
Published Boston, MA American Meteorological Society 01.07.2000
Subjects
Climate
Climate change
Climatic zones
Earth, ocean, space
El Nino
Exact sciences and technology
External geophysics
Global climate models
Meteorology
Ocean currents
Oceanic climates
Oceans
Precipitation
Rain
Sea surface temperature
Troposphere
Water in the atmosphere (humidity, clouds, evaporation, precipitation)
Wave propagation
Waves
White people
Australia
Oceania
Antarctic region
Sea surface
Climate
El Nino
Antarctic circumpolar wave
Southern oscillation
Humidity transfer
Surface temperature
Anomaly
Atmospheric precipitation
Forecast model
Atmospheric humidity
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Summary:Year-to-year changes are found in Australian precipitation (APP) covarying with those in sea surface temperature (SST) and troposphere moisture flux (MF) over the three oceans surrounding Australia for 40 yr from 1958 to 1997. Australia’s wet (dry) years are associated with warm (cool) SST anomalies surrounding Australia and convergent (divergent) MF anomalies directly overhead. Differences in APP (SST) between wet and dry years can reach 0.75 m (1.2°C) in northeast Australia (subtropical Indian Ocean). Wet (dry) years often occur during La Niña (El Niño), but significant differences in covarying SST, MF, and APP anomalies from one El Niño to the next are found, indicating that regional climate changes also influence APP. Covarying SST and MF anomalies on basin space scales and interannual timescales are found to take 2–3 yr to propagate eastward from Africa to Australia. This propagation occurs in association with the Antarctic Circumpolar Wave (ACW) in the Southern Ocean, the north branch of the ACW in the Indian Ocean, and the global El Niño–Southern Oscillation wave in the tropical ocean. A statistical climate prediction system based upon the slow eastward propagation of SST anomalies and their nearly one-to-one relationship with APP anomalies is constructed, yielding significant hindcast skill for predicting interannual APP anomalies at lead times of 1 and 2 yr. Best hindcast skill for the extratropical portion of Australia derives from the ACW south of Australia and the north branch of the ACW west of Australia. Eastward propagation of SST anomalies in these two oceanic domains is capable of predicting more than 50% of the total interannual variance over Victoria and New South Wales and over Western Australia poleward of 20°S over the 40-yr record. This percentage is much better than expected from chance or persistence, demonstrating the importance of the ACW upon year-to-year changes in APP at these latitudes.
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ISSN:0894-8755
1520-0442
DOI:10.1175/1520-0442(2000)013<2125:IOTACW>2.0.CO;2