The Characteristics of 30-60 Day Oscillation and Its Relations to the Interannual Oscillations

Song Yi; Chen Longxun

doi:10.1007/BF02656942

Impact Factor: 5.8

Volume 9 Issue 3

Jul. 1992

Article Contents

Article > ADVANCES IN ATMOSPHERIC SCIENCES > 1992 > 9(3): 323-336

The Characteristics of 30-60 Day Oscillation and Its Relations to the Interannual Oscillations

1.
Chinese Academy of Meteorological Sciences, Beijing 100081,Chinese Academy of Meteorological Sciences, Beijing 100081

doi: 10.1007/BF02656942

Abstract
References
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Abstract:
The characteristics of 30-60 day oscillation (hereafter called LFO ) of the outgoing longwave radiation data (OLR) and its relations to the interannual oscillations of the sea surface temperature (SST) are investigated by using the daily OLR data for the period from January, 1979 to December, 1987 and the corresponding monthly SST data. II is found that the LFO the band the interannual oscillations of the SST monthly anomaly (SSTA) interact each oth-er and they all relate to the occurrence and development of El Nino events closely. Before El Nino event happens, it contributes to the SST’s warming up and to the SST’s quasi-biennial oscillation (called QBO for brevity) and three and half years oscillation (called SO for short) being in warm water phase in the equatorial central and eastern Pacific (ECP and EEP) that the LFO in the equatorial western Pacific (EWP) enhances and propagates eastward; When El Nino event takes place, the LFO, SSTA and SSTA’s QBO and SO in the EEP interact and strengthen each other; But the warmer SST and the SSTA’s QBO and SO in the warm water phase in the EEP contribute to the LFO's weak-ening in the equatorial Pacific. Moreover, these contribute to the SST in the EEP becoming cold and the SSTA’s QBO and SO in the EWP being in cold water phase and then impel the El Nino event to end.
References

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Manuscript History

Manuscript received: 10 July 1992

Manuscript revised: 10 July 1992

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

The Characteristics of 30-60 Day Oscillation and Its Relations to the Interannual Oscillations

1. Chinese Academy of Meteorological Sciences, Beijing 100081,Chinese Academy of Meteorological Sciences, Beijing 100081

Manuscript received: 1992-07-10
Manuscript revised: 1992-07-10

Abstract: The characteristics of 30-60 day oscillation (hereafter called LFO ) of the outgoing longwave radiation data (OLR) and its relations to the interannual oscillations of the sea surface temperature (SST) are investigated by using the daily OLR data for the period from January, 1979 to December, 1987 and the corresponding monthly SST data. II is found that the LFO the band the interannual oscillations of the SST monthly anomaly (SSTA) interact each oth-er and they all relate to the occurrence and development of El Nino events closely. Before El Nino event happens, it contributes to the SST’s warming up and to the SST’s quasi-biennial oscillation (called QBO for brevity) and three and half years oscillation (called SO for short) being in warm water phase in the equatorial central and eastern Pacific (ECP and EEP) that the LFO in the equatorial western Pacific (EWP) enhances and propagates eastward; When El Nino event takes place, the LFO, SSTA and SSTA’s QBO and SO in the EEP interact and strengthen each other; But the warmer SST and the SSTA’s QBO and SO in the warm water phase in the EEP contribute to the LFO's weak-ening in the equatorial Pacific. Moreover, these contribute to the SST in the EEP becoming cold and the SSTA’s QBO and SO in the EWP being in cold water phase and then impel the El Nino event to end.