Scientists from the Guangdong Ocean University published a study quantitatively examining and comparing the intensity of monsoons.
Monsoons are seasonal weather conditions that typically a result of reversing wind accompanied by corresponding changes in precipitation. It is also used to describe seasonal alterations in atmospheric circulation and rainfall associated with the asymmetric temperature rise of land and sea.
The Indian summer monsoon (ISM) and western North Pacific summer monsoon (WNPSM) are two major subcomponents of the Asian summer monsoon. Studying the changes in ISM and WNPSM are important to understanding how these monsoons could affect socio-economic conditions and also dive deeper in to the scientific causes.
In a study published in Atmospheric and Oceanic Science Letters, by authors from the Guangdong Ocean University, quantitatively examined and compared the intensity of the interannual variability (IIV) of the monsoon and monsoon-ENSO biennial relationship (MEBR) for both the ISM and WNPSM.
“Our results reveal interesting multidecadal seesaw patterns of the ISM and WNPSM in terms of their IIV and MEBR, which could be triggered by the increasing influences from the tropical Atlantic Ocean,” says Dr Wang Lei, the corresponding author of this study.
Out-of-phase co-variability was observed between the ISM and WNPSM. When the IIV and MEBR of the ISM were strong (weak) before (after) the mid-1980s, the IIV and MEBR of the WNPSM tended to be weak (strong). During the period with a stronger ENSO-Atlantic (ENSO-Indian Ocean) coupling, the IIV and MEBR of the WNPSM (ISM) were observed to be stronger.
The increasing influences from the tropical Atlantic Ocean sea surface temperature (SST) could exert different influences on the ISM and WNPSM, leading to changes in opposite signs of the two monsoons in terms of IIV and MEBR. Increasing influences from the tropical Atlantic SST may be related to its persistent warming trend due to combined effects from the global warming trend and the recent phase change of the Atlantic multidecadal oscillation.
“These results imply that tropical Atlantic SST may need to be given more attention when predicting future monsoon variability of the ISM and WNPSM,” concludes Dr Wang.
“More studies are needed in the future to better understand the inter-basin interactions among the tropical Pacific, Atlantic, and Indian Ocean basins, and their interdecadal changes, which may be the key to understanding the recent climate variability.” [APBN]