Africa Advancement Indicators 2012/13 (Globe Financial Institution, Washington, DC, 2013).
Google Scholar.
McDonald, K., Bosshard, P. & & Maker, N. Exporting dams: China’s hydropower market goes worldwide. J. Env. Manag. 90, S294– S302 (2009 ).
Google Scholar.
Dong, B. & & Sutton, R. Leading function of greenhouse-gas requiring in the recuperation of Sahel rains. Nat. Clim. Adjustment 5, 757– 760 (2015 ).
Google Scholar.
Conway, D. et al. Rainfall as well as water sources irregularity in sub-Saharan Africa throughout the 20th century. J. Hydrom. 10, 41– 59 (2009 ).
Google Scholar.
Mason, S. J. & & Court, M. R. Environment irregularity as well as adjustment over southerly Africa: a representation on underlying procedures. Prog. Phys. Geog. 21, 23– 50 (1997 ).
Google Scholar.
Schaeffer, R. et al. Power market susceptability to environment adjustment: a testimonial. Power 38, 1– 12 (2012 ).
Google Scholar.
Casal, M. Jr Dry spell: Hydropower’s Achilles heel International Rivers (16 May 2016).
Dams as well as Power Sectors Interdependency Research (DOE, 2011).
Thompson, J. Mapping dry spell’s effect on electrical power generation High Nation Information (7 July 2015).
de Lucena, A. F. P., Schaeffer, R. & & Szklo, A. S. Least-cost adjustment choices for worldwide environment adjustment influence on the Brazilian electrical power system. Chunk. Environ. Adjustment 20, 342– 350 (2010 ).
Google Scholar.
Poindexter, G. B. 2016 Dry spell proceeds as well as alleviates in Brazil, influencing hydroelectric power generation Hydroworld (3 January 2016).
Eberhard, A., Rosnes, O., Shkaratan, M. & & Vennemo, H. Africa’s Power Framework: Financial Investment, Assimilation, Performance (Globe Financial Institution, Washington, 2011).
Beilfuss R. A. Risky environment for southerly African hydro: evaluating hydrological threats as well as effects for Zambezi River basin dams International Rivers (19 September 2012).
Sanji, K. Malawi’s hydropower runs out as river runs reduced, enormous woodlands Reuters (29 October 2015).
Tanzania shutting hydropower plants BBC (9 October 2015).
Zambia to strengthen power cuts after dry spell impacts hydro plant Reuters (1 September 2015).
Kozacek, C. Zambia electrical power scarcity highlights Africa’s hydropower deficiencies Waternews (22 July 2015).
The PIDA Power Vision (Program for Framework Advancement in Africa, 2016).
Richard, Y., Trzaska, S., Roucou, P. & & Rouault, M. Adjustment of the southerly African rains variability/ENSO connection given that the late 1960s. Clim. Dyn. 16, 883– 895 (2000 ).
Google Scholar.
Conway, D., Hanson, C. E., Doherty, R. & & Persechino, A. GCM simulations of the Indian Sea dipole impact on Eastern African rains: Future as well as existing. Geophys. Res. Lett. 34, L03705 (2007 ).
Google Scholar.
Eltahir, E. A. El Niño as well as the all-natural irregularity in the circulation of the Nile River. Water. Resour. Res. 32, 131– 137 (1996 ).
Google Scholar.
Cervigni, R., Liden, R., Neumann, J. E. & & Strzepek, K. M. Enhancing the Environment Strength of Africa’s Framework: The Power as well as Water Sectors (Globe Financial Institution, Washington DC, 2015).
Google Scholar.
Conway, D. & & Hulme, M. Current changes in rainfall as well as drainage over the Nile subbasins as well as their influence on Key Nile discharge. Weather Adjustment 25, 127– 151 (1993 ).
Google Scholar.
Court, M. R. The systematic irregularity of African river streams: composite environment framework as well as the Atlantic blood circulation. Water SA 29, 1– 10 (2003 ).
Dieppois, B., Rouault, M. & & New, M. The influence of ENSO on Southern African rains in CMIP5 sea environment combined environment versions. Clim. Dyn. 45, 2425– 2442 (2015 ).
Google Scholar.
Bowen, B. H., Sparrow, F. T. & & Yu, Z. Modeling electrical power profession plan for the twelve countries of the Southerly African Power Swimming Pool (SAPP). Util. Plan 8, 183– 197 (1999 ).
Google Scholar.
Southerly African Power Swimming Pool Yearly Record 2014 (SAPP, 2014).
Olukoju, A. ‘Never Ever Anticipate Power Always’: electrical power customers’ feedback to syndicate, corruption as well as ineffective solutions in Nigeria. Afr. Aff. 103, 51– 71 (2012 ).
Google Scholar.
Escribano, A., Luis Guasch, J. & & Pena, J. Evaluating the Influence of Framework High Quality on Company Efficiency in Africa; Cross Nation Comparisons based upon Financial investment Environment Studies from 1999 to 2005. Plan Study Working Paper 5191 (Globe Financial Institution, 2010).
Sheffield, J. et al. A dry spell tracking as well as projecting system for sub-Sahara African water sources as well as food safety. Bull. Am. Meteorol. Soc. 95, 861– 882 (2014 ).
Google Scholar.
Eberhard, A., Gratwick, K., Morello, E. & & Antmann, P. Accelerating financial investments in power in sub-Saharan Africa. Nat. Power 2, 17005 (2017 ).
Google Scholar.
Africa Development Panel. Lights, Power, Activity: Electrifying Africa (Africa Development Panel, Geneva, 2017).
van Vliet, M. T. H., Wiberg, D., Leduc, S. & & Riahi, K. Power-generation system susceptability as well as adjustment to modifications in environment as well as water sources. Nat. Clim. Adjustment 6, 375– 380 (2016 ).
Google Scholar.
Kling, H., Stanzel, P. & & Preishuber, M. Influence modelling of water sources growth as well as environment circumstances on Zambezi River release. J. Hydrol. Reg. Stud. 1, 17– 43 (2014 ).
Google Scholar.
Spalding-Fecher, R., Joyce, B. & & Winkler, H. Environment adjustment as well as hydropower in the Southerly African Power Swimming Pool as well as Zambezi River Container: system-wide effects as well as plan effects. Power Plan. 103, 84– 97 (2017 ).
Google Scholar.
Hellmuth, M., Cookson, P. & & Potter, J. Attending To Environment Susceptability for Power System Strength as well as Power Safety And Security (RALI, 2017).
Zhang, Q., Körnich, H. & & Holmgren, K. Just how well do reanalyses stand for the southerly African rainfall? Clim. Dyn. 40, 951– 962 (2013 ).
Google Scholar.
Maidment, R. I., Allan, R. P. & & Black, E. Current observed as well as substitute modifications in rainfall over Africa. Geophys. Res. Lett. 42, 8155– 8164 (2015 ).
Google Scholar.
Richman, M. B. Turning of major parts. Int. J. Climatol. 6, 293– 335 (1986 ).
Google Scholar.
Mimmack, G. M., Mason, S. J. & & Galpin, J. S. Option of range matrices in collection evaluation: specifying areas. J. Clim. 14, 2790– 2797 (2001 ).
Google Scholar.
Becker, A. et al. A summary of the worldwide land-surface rainfall information items of the Worldwide Rainfall Meteorology Centre with example applications consisting of centennial (fad) evaluation from 1901– existing. Planet Syst. Sci. Information 5, 71– 99 (2013 ).
Google Scholar.
GEO Global Power Observatory ( accessed 10 January 2017); http://globalenergyobservatory.org.
Hydropower Standing Record (International Hydropower Organization, 2015).
Rivers, Lake Centerlines (Natural Planet, accessed 02-09-16); http://www.naturalearthdata.com/downloads/50m-physical-vectors/50m-rivers-lake-centerlines/.
Harris, I., Jones, P. D., Osborn, T. J. & & Lister, D. H. Updated high-resolution grids of regular monthly weather monitorings– the CRU TS3.10 dataset. Int. J. Climatol. 34, 623– 642, https://doi.org/10.1002/joc.3711 (2014 ).
Google Scholar.
