Abstract
AbstractThe East African precipitation seasonal cycle is of significant societal importance, and yet the current generation of coupled global climate models fails to correctly capture this seasonality. The use of convective parameterization schemes is a known source of precipitation bias in such models. Recently, a high-resolution regional model was used to produce the first pan-African climate change simulation that explicitly models convection. Here, this is compared with a corresponding parameterized-convection simulation to explore the effect of the parameterization on representation of East Africa precipitation seasonality. Both models capture current seasonality, although an overestimate in September–October in the parameterized simulation leads to an early bias in the onset of the boreal autumn short rains, associated with higher convective instability and near-surface moist static energy. This bias is removed in the explicit model. Under future climate change both models show the short rains getting later and wetter. For the boreal spring long rains, the explicit convection simulation shows the onset advancing but the parameterized simulation shows little change. Over Uganda and western Kenya both simulations show rainfall increases in the January–February dry season and large increases in boreal summer and autumn rainfall, particularly in the explicit convection model, changing the shape of the seasonal cycle, with potential for pronounced socioeconomic impacts. Interannual variability is similar in both models. Results imply that parameterization of convection may be a source of uncertainty for projections of changes in seasonal timing from global models and that potentially impactful changes in seasonality should be highlighted to users.
Highlights
Recent extreme wet seasons over East Africa have had a range of serious socioeconomic consequences; the successive failure of the 2018 short rains (October–December) and the 2019 long rains (March–May) led to drought and decreased food security in Kenya in mid-2019
This region is used to define the part of East Africa that experiences a biannual rainfall regime and is used throughout the paper; it is the same region as is used in Wainwright et al (2019) and is similar to the region used in Rowell et al (2015)
This is true of both wet seasons; while we would expect the interannual variability in the short rains to be driven by larger-scale factors, from outside the regional domain [such as El Niño–Southern Oscillation (ENSO) and the Indian Ocean dipole (IOD); Nicholson 2017], these results confirm that in these simulations the interannual variability in the long rains is largely controlled by the combination of the sea surface temperature (SST) and atmospheric boundary conditions
Summary
Recent extreme wet seasons over East Africa have had a range of serious socioeconomic consequences; the successive failure of the 2018 short rains (October–December) and the 2019 long rains (March–May) led to drought and decreased food security in Kenya in mid-2019. Above average rainfall was experienced during the 2018 long rains (Kilavi et al 2018; Finney et al 2020b) and 2019 short rains, with many locations receiving more than double the climatological rainfall during October–December 2019 (Wainwright et al 2020). The anomalously wet short rains in 2019 led to flooding and landslides, with an estimated 2.8 million people affected across East Africa. This was followed by a wet 2020 long rains leading to a large and rapid rise in the level of Lake Victoria in early.
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