Study title

Climate change is anticipated to have long-term effects on hydrological processes and patterns that lead to water stress in agro-ecological catchments. Climate change escalates water scarcity in the Usangu catchment, evidenced by drying up of rivers during dry season. Therefore, this study was undertaken to assess climate change impacts on hydrology by utilizing SWAT model and an ensemble mean of five Global Circulation Models (GCMs) under two shared socio-economic pathways (SSPs) emission scenarios. Downscaling of GCMs was performed by LARS-WG statistical downscaling tool. In comparison to the baseline period, short rain intervals are expected to occur between 2030 and 2060, with mean annual precipitation increase of 7% and 17% in SSP 2-4.5 and SSP 5-8.5 respectively. Maximum and minimum temperatures are expected to rise by 0.6°C-2°C. Corresponding to future temperature increase, evapotranspiration would increase to about 30% and decrease more water yield and groundwater recharge by 7% and 26% in SSP 2-4.5 than in SSP 5-8.5. However, the effect of precipitation increase is shown by increased surface runoff and streamflow during wetter months. These findings provide watershed managers with crucial information for planning and managing the catchment in light of a changing climate.Sustainable water resource development remains elusive because development has largely externalized costs to the environment and vulnerable people. There is a need for novel research theory, methodologies & practice in order to meet the UN SDGs and realise the Africa Water Vision 2025. We propose to launch an innovative research approach: the Adaptive Systemic Approach (ASA). Our aim is to apply transformative, transdisciplinary, community-engaged research, to shift water development outcomes towards achieving the SDGs. We focus on continental water development priorities: water supply and pollution. This collaboration brings together the ARUA Water Centre of Excellence (CoE) and UK...