Abstract
Based on Remote Sensing Systems-retrieved temperature data in the period of January 1979 to February 2016, the response of stratospheric and tropospheric temperature in boreal winter to two previously defined types of El Niño [spring (SP) and summer (SU)] is investigated. The results show that, the response of temperature under SP onset involves a significant positive anomaly, with a symmetric distribution about the equator over the Indian Ocean region in the lower troposphere (850 hPa) and a negative anomaly in the lower stratosphere (50 hPa). Meanwhile, in the area 30°N and 30°S of the equator, most parts of the lower stratosphere feature a positive anomaly. This indicates that SP El Niño events are more conducive than SU events to warming the lower stratosphere. The atmospheric circulation structure over the tropical Indian Ocean is beneficial to the upward transfer of warm air to the upper layer. In contrast, the structure over the tropical Pacific Ocean favors the warming of upper air. On the other hand, the Eliassen–Palm (EP) flux is small and the heat flux is negative during SP-type events. Thus, the EP flux and Brewer–Dobson circulation decrease, making the temperature higher in the upper troposphere-lower stratosphere region at low latitudes.
Highlights
The El Nino-Southern Oscillation (ENSO) is the strongest annual-scale air-sea interaction phenomenon in the tropical Pacific
This is because completely different patterns of propagation and dissipation of ultralong Rossby waves in the mid-latitude stratosphere are caused by the gradient patterns of sea surface temperature anomalies (SSTAs) in the two types of El Nino events
The difference in the Indian Ocean region is not statistically significant but shows a negative anomaly that is symmetric about the equator
Summary
The El Nino-Southern Oscillation (ENSO) is the strongest annual-scale air-sea interaction phenomenon in the tropical Pacific. Previous research has indicated that strong ENSO events enhance tropical upwelling and stratosphere-troposphere exchange (STE) This change in upwelling and STE plays an important role in the atmospheric composition and structure of the upper troposphere-lower stratosphere (UTLS) region. Canonical El Nino and El Nino Modoki events can lead to profoundly different effects on stratospheric temperature and circulation [20,21,22] This is because completely different patterns of propagation and dissipation of ultralong Rossby waves in the mid-latitude stratosphere are caused by the gradient patterns of SSTAs in the two types of El Nino events. Because of the difference in the timing, intensity, and causes of these two types of El Nino, it follows that there is likely to be a different tropospheric and stratospheric temperature response We investigate this assertion in the present study
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