Observations and high-resolution simulations of convective precipitation organization over the tropical Atlantic

Brune, Sebastian ORCIDiD
Buschow, Sebastian ORCIDiD
Friederichs, Petra ORCIDiD

DOI: https://doi.org/10.1002/qj.3751
Persistent URL: http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/9443
Brune, Sebastian; Buschow, Sebastian; Friederichs, Petra, 2020: Observations and high-resolution simulations of convective precipitation organization over the tropical Atlantic. In: Quarterly Journal of the Royal Meteorological Society, 146, 729, 1545-1563, DOI: https://doi.org/10.1002/qj.3751. 

Abstract

High-resolution simulations (grid spacing 2.5 km) are performed with ICON-LEM to characterize convective organization in the Tropics during August 2016 over a large domain ranging from northeastern South America, along the tropical Atlantic to Africa (8,000×3,000 km). The degree of organization is measured by a refined version of the wavelet-based organization index (WOI), which is able to characterize the scale, the intensity and anisotropy of convection based on rain rates alone. Exploiting the localization of wavelets both in space and time, we define a localized version of the convective organization index (LWOI). We compare convection observed in satellite-derived rain rates with the corresponding processes simulated by ICON-LEM. Model and observations indicate three regions with different kinds of convective organization. Continental convection over West Africa has a predominantly meridional orientation and is more organized than over South America, because it acts on larger scales and is more intense. Convection over the tropical Atlantic is zonally oriented along the ITCZ and less intense. ICON and observations agree on the number and intensity of the African easterly waves during the simulation period. The waves are associated with strong vorticity anomalies and are clearly visible in a spatiotemporal wavelet analysis. The central speed and the wavelength of the waves is simulated well. Both the scale and intensity components of LWOI in ICON are significantly correlated with environmental variables. The scale of precipitation is related to wind shear, CAPE and its tendency, while the intensity strongly correlates with column-integrated humidity, upper-level divergence and maximum vertical wind speed. This demonstrates that the LWOI components capture important characteristics of convective precipitation.