Abstract
Unlike other tropical ocean basins, the Bay of Bengal (BoB) has two tropical cyclone (TC) seasons: a pre-monsoon season (Pre-MS) and a post-monsoon season (Post-MS). More interestingly, during the period from 1981 to 2016, the global maximum and minimum formation rates of super cyclones (SCs, categories 4 and 5) occurred in the Pre-MS and Post-MS, respectively, in the BoB. Methods including Butterworth filter, box difference index analysis and quantitative diagnosis were utilized herein to detect what and how background environmental factors cause significantly different SC formation rates between the Pre- and Post-MS. Diagnosis results revealed that the vertical temperature difference (VTD) mainly determines whether TCs can develop into SCs during the Post-MS, similar to Pre-MS. It’s in agreement with previous studies demonstrating that the VTD is controlled by the low-level temperature during the Post-MS but is determined by the upper-level temperature during the Pre-MS. The results also revealed that the background sea surface temperature is much higher in the Pre-MS than in the Post-MS and forces higher 1000 hPa-level air temperature. Additionally, there is higher saturated specific humidity (qs) due to the higher temperature in the Pre-MS. The differences in the bottom-level temperature and qs cooperate to predominantly contribute to the significant difference in Vpot2, which could denote the maximum potential intensity of TC, eventually leading to the remarkably different SC formation rates between the Pre- and Post-MS in the BoB.
Highlights
Tropical cyclones (TCs) are severe weather systems and one of the most frequent natural disasters, and they are likely to strike the coastal regions of tropical oceans (Emanuel 2003; Pielke et al 2008; Blake et al 2011; Li et al 2013)
According to the statistical analysis, there is a unique phenomenon in which the SC formation rates in the Bay of Bengal (BoB) reach the global maximum and minimum during the Pre- and PostMS, respectively
The significant difference in vertical temperature difference (VTD) between the SC and TC groups is principally due to the upper-level T variation during the pre-monsoon season (Pre-MS)
Summary
Tropical cyclones (TCs) are severe weather systems and one of the most frequent natural disasters, and they are likely to strike the coastal regions of tropical oceans (Emanuel 2003; Pielke et al 2008; Blake et al 2011; Li et al 2013). TC Nargis (Webster 2008; Kikuchi et al 2009; Lin et al 2009; McPhaden et al 2009; Yanase et al 2010), which struck the southern coast of Myanmar on 2 May 2008, caused the worst natural disaster in the recorded history of Myanmar Such tremendous socioeconomic implications call for a better understanding of the mechanisms responsible for intensifying TCs over the BoB to improve TC intensity operational forecasts and projected changes in a warming world. Unlike those over the NWP, NEP, NA, SP and SIO, TCs over the BoB have an annual cycle with a distinctly bimodal distribution, wherein TCs occur mostly during the premonsoon season (Pre-MS, April–May) and post-monsoon.
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