A Lagrangian perspective on the lifecycle and cloud radiative effect of deep convective clouds over Africa
Atmospheric Chemistry and Physics European Geosciences Union 24:9 (2024) 5165-5180
Authors:
William K Jones, Martin Stengel, Philip Stier
Abstract:
The anvil clouds of tropical deep convection have large radiative effects in both the shortwave (SW)
and longwave (LW) spectra with the average magnitudes of both over 100 Wm−2
. Despite this, due to the
opposite sign of these fluxes, the net average of the anvil cloud radiative effect (CRE) over the tropics is observed
to be neutral. Research into the response of the anvil CRE to climate change has primarily focused on the
feedbacks of anvil cloud height and anvil cloud area, in particular regarding the LW feedback. However, tropical
deep convection over land has a strong diurnal cycle which may couple with the shortwave component of the
anvil cloud radiative effect. As this diurnal cycle is poorly represented in climate models it is vital to gain a better
understanding of how its changes impact the anvil CRE.
To study the connection between the deep convective cloud (DCC) lifecycle and CRE, we investigate the behaviour of both isolated and organised DCCs in a 4-month case study over sub-Saharan Africa (May–August
2016). Using a novel cloud tracking algorithm, we detect and track growing convective cores and their associated anvil clouds using geostationary satellite observations from the Meteosat Spinning Enhanced Visible and
Infrared Imager (SEVIRI). Retrieved cloud properties and derived broadband radiative fluxes are provided by the
Community Cloud retrieval for CLimate (CC4CL) algorithm. By collecting the cloud properties of the tracked
DCCs, we produce a dataset of anvil cloud properties along their lifetimes. While the majority of DCCs tracked
in this dataset are isolated, with only a single core, the overall coverage of anvil clouds is dominated by those of
clustered, multi-core anvils due to their larger areas and lifetimes.
We find that the anvil cloud CRE of our tracked DCCs has a bimodal distribution. The interaction between the
lifecycles of DCCs and the diurnal cycle of insolation results in a wide range of the SW anvil CRE, while the
LW component remains in a comparatively narrow range of values. The CRE of individual anvil clouds varies
widely, with isolated DCCs tending to have large negative or positive CREs, while larger, organised systems tend
to have a CRE closer to 0. Despite this, we find that the net anvil cloud CRE across all tracked DCCs is close to
neutral (−0.94 ± 0.91 Wm−2
). Changes in the lifecycle of DCCs, such as shifts in the time of triggering, or the
length of the dissipating phase, could have large impacts on the SW anvil CRE and lead to complex responses
that are not considered by theories of LW anvil CRE feedbacks. </jats:p>
