Investigating changes in rainfall seasonality across South Africa: 1987–2016

Roffe, Sarah J.; Fitchett, Jennifer M.; Curtis, C. J.

doi:10.1002/joc.6830

Cited by 23 publications

(10 citation statements)

References 90 publications

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“…In the past decades, early rainfall in the catchment usually commences at the beginning of spring month (September), which prompted the starting of planting season; however, this has now shifted to October-November due to climate change (Shoko et al 2019). Similar findings were also reported in Roffe et al (2020), indicating the delay in wet season start date along with a reduction in summer wet season rainfall.…”

Section: Discussionmentioning

confidence: 54%

Assessment of smallholder farmers’ perception and adaptation response to climate change in the Olifants catchment, South Africa

Olabanji

Davis

Ndarana

et al. 2021

Journal of Water and Climate Change

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Climate change is expected to affect the livelihood of rural farmers in South Africa particularly the smallholder farmers, due to their overwhelming dependence on rain-fed agriculture. This study examines smallholder farmers' perception of climate change, the adaptation strategies adopted and factors that influences their adaptive decisions. The unit of data collection was household interview and focus group discussion. Climate data for the Olifants catchment (1986–2015) were also collected to validate farmers' perception of climate change with actual climate trend. Data collected were analysed using descriptive statistics, Mann–Kendall trend, Sen's slope estimator and multinomial logit regression model. Results revealed that smallholder farmers are aware of climate change (98%), their perception of these changes aligns with actual meteorological data, as the Mann–Kendall test confirms a decreasing inter-annual rainfall trend (−0.172) and an increasing temperature trend (0.004). These changes in temperature and precipitation have prompted the adoption of various adaptation responses, among which the use of improved seeds, application of chemical fertilizer and changing planting dates were the most commonly practised. The main barriers to the adoption of adaptation strategies were lack of access to credit facility, market, irrigation, information about climate change and lack of extension service. The implication of this study is to provide information to policy-makers on the current adaptation responses adopted by farmers and ways in which their adaptive capacity can be improved in order to ensure food security.

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Section: Discussionmentioning

confidence: 54%

Assessment of smallholder farmers’ perception and adaptation response to climate change in the Olifants catchment, South Africa

Olabanji

Davis

Ndarana

et al. 2021

Journal of Water and Climate Change

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“…Thus, SA is regarded as a climate change hotspot [27]. Several studies (e.g., [4,25,28,29]) have pointed to exacerbating situations, with an overall decrease in SA seasonal precipitation over the last century. However, SA's large zonal and meridional extent leads to significant differences in local precipitation characteristics.…”

Section: Introductionmentioning

confidence: 99%

Multi-Decadal Variability and Future Changes in Precipitation over Southern Africa

et al. 2021

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The future planning and management of water resources ought to be based on climate change projections at relevant temporal and spatial scales. This work uses the new regional demarcation for Southern Africa (SA) to investigate the spatio-temporal precipitation variability and trends of centennial-scale observation and modeled data, based on datasets from the sixth phase of the Coupled Model Intercomparison Project (CMIP6). The study employs several statistical methods to rank the models according to their precipitation simulation ability. The Theil–Sen slope estimator is used to assess precipitation trends, with a Student’s t-test for the significance test. The comparison of observation and model historical data enables identification of the best-performing global climate models (GCMs), which are then employed in the projection analysis under two Shared Socioeconomic Pathways (SSPs): SSP2-4.5 and SSP5-8.5. The GCMs adequately capture the annual precipitation variation but with a general overestimation, especially over high-elevation areas. Most of the models fail to capture precipitation over the Lesotho-Eswatini area. The three best-performing GCMs over SA are FGOALS-g3, MPI-ESM1-2-HR and NorESM2-LM. The sub-regions demonstrate that precipitation trends cannot be generalized and that localized studies can provide more accurate findings. Overall, precipitation in the wet and dry seasons shows an initial increase during the near future over western and eastern SA, followed by a reduction in precipitation during the mid- and far future under both projection scenarios. Madagascar is expected to experience a decrease in precipitation amount throughout the twenty-first century.

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“…Notably, the SQMKT results for the scores and wetseason length appear to broadly track each other in direction throughout 1841-2020 (Fig. 3a, d), thus highlighting good agreement between the two methods (Roffe et al 2021a). The U(t) line re ects cyclic patterns, with periods of stronger and weaker seasonality (Fig.…”

Section: Rainfall Seasonality Shifts: 1841-2020mentioning

confidence: 59%

“…Using this metric, summer-, winter-and year-round rainfall regimes are distinguished primarily through the wet-season timing and duration, where WRZ conditions are classi ed when the wet-season is shorter than nine months (~ 270 days) and includes the winter solstice, but not the summer solstice (Roffe et al 2020). For the wet-season, we quanti ed annual start-and end-dates, length, total rainfall, number of rain days and daily rainfall rate (Roffe et al 2020(Roffe et al , 2021a. As wet-season start-and end-dates broadly equate to dry-season end-and start-dates, respectively, and can be used to infer the dry-season length, only the dry-season total rainfall, number of rain days and daily rainfall rate were calculated.…”

Section: Quantifying Rainfall Seasonalitymentioning

confidence: 99%

South African winter rainfall zone shifts: A comparison of seasonality metrics for Cape Town from 1841–1899 and 1933–2020

Roffe

Steinkopf

Fitchett

2022

Theor Appl Climatol

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Mounting evidence across South Africa's southwestern winter rainfall zone (WRZ) re ects consistent drying since ~1980 and projected trends suggest this will continue. However, limited evidence exists for the region's rainfall seasonality changes. To improve our understanding of these WRZ drying trends, especially within the context of Cape Town's 2015-2017 "Day Zero" drought, it is necessary to explore long-term rainfall seasonality trends. Thus, we use the longest WRZ meteorological record from the South African Astronomical Observatory (SAAO) in Cape Town to investigate rainfall seasonality shifts during 1841-2020. Consistent with recorded poleward migrations of the subtropical high-pressure belt and mid-latitude westerlies, known drivers behind the drought and drying trends, calculated trends demonstrate strengthening of WRZ conditions, primarily from a later start-date trend leading to a shorter wet-season. Long-term drying trends are quanti ed for the wet-and dry-seasons, however, analysis of trend evolution reveals much variability, re ecting that drying has only persisted since ~1892. Comparative analyses of the rst and last 59 years of 1841-2020 reveals a rainfall decline of ~10% across both seasons -highlighting that the extreme "Day Zero" drought was not only driven by wet-season rainfall declines. Results demonstrate that these drying trends were consistently driven by a long-term decline in rain day counts and a more recent decline in average rainfall per rain day. Correspondence between our results and projected rainfall seasonality trends suggests the trends we quanti ed will likely continue, thus improvements and continuation of existing water conservation and management strategies are imperative for Cape Town. IntroductionThe southwestern region of South Africa's winter rainfall zone (WRZ; Fig. 1) experienced below-average rainfall during the 2015-2017 April-September winter wet-seasons, which resulted in the worst drought and water shortages across the region since 1904 (Botai et al. 2017;Wolski 2018). These de cits, which were most pronounced for the autumn (March-May) and spring transition (September-November) seasons, led to supply dam water levels dropping to ~ 20% capacity during May 2018 (Burls et al. 2019;Pascale et al. 2020). For the ~ 4 million inhabitants of the City of Cape Town, this culminated in an imminent threat that dam levels would fall below ~ 10%, marking the level at which the city's municipal water supply would have been disconnected, before the 2018 winter wet-season (Sousa et al. 2018). The fear surrounding this gathered much attention, with media and municipal authorities terming this event "Day Zero", and forced the city to enforce strict water restrictions, from pre-drought levels of ~ 200L per person per day to 50L per person per day (Muller 2018; Wolski 2018). Fortunately, "Day Zero" was averted as good early winter rains and near-average rainfall for the 2018 winter season led to dam levels rising to ~ 70% by October 2018 (Sousa et al. 2018;Burls et al. 2019). This c...

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Investigating changes in rainfall seasonality across South Africa: 1987–2016

Cited by 23 publications

References 90 publications

Assessment of smallholder farmers’ perception and adaptation response to climate change in the Olifants catchment, South Africa

Assessment of smallholder farmers’ perception and adaptation response to climate change in the Olifants catchment, South Africa

Multi-Decadal Variability and Future Changes in Precipitation over Southern Africa

South African winter rainfall zone shifts: A comparison of seasonality metrics for Cape Town from 1841–1899 and 1933–2020

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