Variability in vertical structure of precipitation with sea surface temperature over the Arabian Sea and the Bay of Bengal as inferred by Tropical Rainfall Measuring Mission precipitation radar measurements

Saikranthi, Kadiri and Radhakrishna, Basivi and Rao, Thota Narayana and Satheesh, Sreedharan Krishnakumari (2019) Variability in vertical structure of precipitation with sea surface temperature over the Arabian Sea and the Bay of Bengal as inferred by Tropical Rainfall Measuring Mission precipitation radar measurements. In: ATMOSPHERIC CHEMISTRY AND PHYSICS, 19 (15). pp. 10423-10432.

Preview	PDF atm_che_phy_19-15_10432_2019.pdf - Published Version Download (6MB) | Preview
Preview	PDF acp-19-10423-2019-supplement.pdf - Published Supplemental Material Download (520kB) | Preview

Abstract

Tropical Rainfall Measuring Mission (TRMM) precipitation radar measurements are used to examine the variation in vertical structure of precipitation with sea surface temperature (SST) over the Arabian Sea (AS) and Bay of Bengal (BOB). The variation in reflectivity and precipitation echo top with SST is remarkable over the AS but small over the BOB. The reflectivity increases with SST (from 26 to 31 degrees C) by similar to 1 and 4 dBZ above and below 6 km, respectively, over the AS, while its variation is < 0.5 dBZ over the BOB. The transition from shallow storms at lower SSTs (<= 27 degrees C) to deeper storms at higher SSTs is strongly associated with the decrease in stability and mid-tropospheric wind shear over the AS. In contrary, the storms are deeper at all SSTs over the BOB due to weaker stability and mid-tropospheric wind shear. At lower SSTs, the observed high aerosol optical depth (AOD) and low total column water (TCW) over AS results in the small cloud effective radius (CER) and weaker reflectivity. As SST increases, AOD decreases and TCW increases, leading to a large CER and high reflectivity. The changes in these parameters with SST are marginal over the BOB and hence the CER and reflectivity. The predominance of collision-coalescence process below the bright band is responsible for the observed negative slopes in the reflectivity over both the seas. The observed variations in reflectivity originate at the cloud formation stage over both the seas, and these variations are magnified during the descent of hydrometeors to the ground.

Item Type:	Journal Article
Publication:	ATMOSPHERIC CHEMISTRY AND PHYSICS
Publisher:	COPERNICUS GESELLSCHAFT MBH
Additional Information:	copyright for this article belongs to COPERNICUS GESELLSCHAFT MBH
Department/Centre:	Division of Mechanical Sciences > Centre for Atmospheric & Oceanic Sciences
Date Deposited:	17 Sep 2019 10:47
Last Modified:	17 Sep 2019 10:47
URI:	http://eprints.iisc.ac.in/id/eprint/63560

Actions (login required)

View Item