loading page

Understanding the influence of climate variability on surface water hydrology in the Congo basin
  • +2
  • Christopher E. Ndehedehe,
  • Christopher E Ndehedehe,
  • G Ferreira,
  • Augusto Getirana,
  • Nathan O Agutu
Christopher E. Ndehedehe
School of Environment & Science, Griffith University, Nathan, Queensland 4111, Australia

Corresponding Author:[email protected]

Author Profile
Christopher E Ndehedehe
Australian Rivers Institute
Author Profile
G Ferreira
Hohai University
Author Profile
Augusto Getirana
NASA Goddard Space Flight Center
Author Profile
Nathan O Agutu
Department of Geomatic Engineering and Geospatial Information Systems JKUAT, Nairobi, Kenya
Author Profile


Understanding the impacts of climate on surface water hydrology is required to predict consequences and implications on freshwater habitats, ecological assets, and wetland functions. Although the Congo basin is considerably a freshwater-rich region, largely characterised by numerous water resources after the similitude of the Amazon basin, recent accounts of droughts in the basin are indications that even the most humid regions of the world can be affected by droughts and its impacts. Given the scarcity and limited availability of hydrological data in the region, GRACE (Gravity Recovery and Climate Experiment) observations are combined with model and SPEI (standardized precipitation evapotranspiration index) data to investigate the likelihood of such impacts on the Congo basin’s surface water hydrology. By integrating multivariate analysis with support vector machine regression (SVMR), this study provides some highlights on the characteristics (intensity and variability) of drought events and GRACE-derived terrestrial water storage (TWS) and the influence of global climate on the Congo river discharge. The southern section of the basin shows considerable variability in the spatial and temporal patterns of SPEI and extreme droughts over the Congo basin appear to have persisted with more than 40% coverage in 1994. However, there has been a considerable fall in drought intensities since 2007 and coincides with periods of strong positive anomalies in discharge (i.e., 2007-010). GRACE-derived TWS over the Congo basin is driven by annual fluctuations in rainfall (r = 0.81 at three months phase lag) and strong inter-annual variations of river discharge (r = 0.88, α= 0.05). Generally, results show that changes in the surface water variations (from gauge and model output) of the Congo basin is a key component of the GRACE water column. The outputs of the SVMR scheme indicate that global climate through sea surface temperature anomalies of the Atlantic (r = 0.79, α= 0.05), Pacific (r = 0.79, α= 0.05), and Indian (r = 0.74, α= 0.05) oceans are associated with fluctuations in the Congo river discharge, and confirm the importance of climatic influence on surface water hydrology in the Congo basin.
25 Feb 2022Published in Congo Basin Hydrology, Climate, and Biogeochemistry on pages 63-81. 10.1002/9781119657002.ch5