Abstract
Abstract. A renewed focus on southern Africa's winter rainfall zone (WRZ) following the Day Zero drought and water crisis has not shed much light on the spatial patterns of its rainfall variability and climatological seasonality. However, such understanding remains essential in studying past and potential future climate changes. Using a dense station network covering the region encompassing the WRZ, we study spatial heterogeneity in rainfall seasonality and temporal variability. These spatial patterns are compared to those of rainfall occurring under each ERA5 synoptic-scale wind direction sector. A well-defined “true” WRZ is identified with strong spatial coherence between temporal variability and seasonality not previously reported. The true WRZ is composed of a core and periphery beyond which lies a transition zone to the surrounding year-round rainfall zone (YRZ) and late summer rainfall zone. In places, this transition is highly complex, including where the YRZ extends much further westward along the southern mountains than has previously been reported. The core receives around 80 % of its rainfall with westerly or north-westerly flow compared to only 30 % in the south-western YRZ incursion, where below-average rainfall occurs on days with (usually pre-frontal) north-westerly winds. This spatial pattern corresponds closely to those of rainfall seasonality and temporal variability. Rainfall time series of the core and surroundings are very weakly correlated (R2<0.1), also in the winter half-year, implying that the YRZ is not simply the superposition of summer and winter rainfall zones. In addition to rain-bearing winds, latitude and annual rain day climatology appear to influence the spatial structure of rainfall variability but have little effect on seasonality. Mean annual rainfall in the true WRZ exhibits little association with the identified patterns of seasonality and rainfall variability despite the driest core WRZ stations being an order of magnitude drier than the wettest stations. This is consistent with the general pattern of near homogeneity within the true WRZ, in contrast to steep and complex spatial change outside it.
Highlights
Southern Africa’s winter rainfall zone (WRZ) is a climatically and ecologically hyper-diverse and complex region in which Cape Town is situated (Procheset al., 2005; Bradshaw and Cowling, 2014; Wolski et al, 2021)
The dominant one is the summer rainfall zone (SRZ); the others are (2) WRZ, (3) year-round rainfall zone (YRZ) (SRZ), (4) late SRZ (SRZ), and (5) extended SRZ
We study rainfall seasonality and variability in southern Africa’s WRZ in its regional context (South-Western Southern Africa) through the lens of rainfall–wind direction relationships
Summary
Southern Africa’s winter rainfall zone (WRZ) is a climatically and ecologically hyper-diverse and complex region in which Cape Town is situated (Procheset al., 2005; Bradshaw and Cowling, 2014; Wolski et al, 2021). The eco-region’s spatial evolution over long timescales is seen as key to understanding changes in the Southern Hemisphere (SH) westerlies (Chase and Meadows, 2007; Stager et al, 2012). Both ecological diversity and palaeoecological change patterns differ between the WRZ and the YRZ, with considerable uncertainty remaining about patterns of past climate change, in the transitional zones (Chase et al, 2019; Engelbrecht et al, 2019). Disagreements regarding rainfall seasonality and variability in the transitional regions from the WRZ into its surroundings (Roffe et al, 2019) may be a contributing factor
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