Quantifying focused groundwater recharge induced by irrigation surface water reservoirs in crystalline basement areas for complementary irrigation

Bambara, Apolline; Orban, Philippe; Ouedraogo, I.; Hallot, Eric; Guyon, F.; Zangré, A.; Brouyère, Serge

doi:10.3390/w12102880

Article (Scientific journals)

Quantifying focused groundwater recharge induced by irrigation surface water reservoirs in crystalline basement areas for complementary irrigation

Bambara, Apolline; Orban, Philippe; Ouedraogo, I. et al.

2020 • In Water, 12 (10), p. 1-23

Peer reviewed

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https://hdl.handle.net/2268/254603

DOI
10.3390/w12102880

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Keywords :

Groundwater water balance; Hydrochemistry; Piezometry; Recharge; Surface water reservoir; Chemical analysis; Economics; Groundwater resources; Irrigation; Surface waters; Textures; Underground reservoirs; Water management; Water supply; Watersheds; Crystalline basement; Ground water recharge; Physico-chemical analysis; Regional groundwater; Sediment textures; Socio-economic development; Spatiotemporal analysis; Sub-saharan africa; Recharging (underground waters); Burkina Faso

Abstract :

[en] Through the practice of irrigation, surface water reservoirs (SWRs) contribute to the socio-economic development and food production activities of populations in Sub-Saharan Africa (SSA). However, they tend to dry up prematurely. One solution to circumvent these irrigation water shortages is to ensure their conjunctive use with groundwater. The objective of this study is to better understand the contribution of SWRs to groundwater recharge and to determine if groundwater may be considered as a complementary local resource for irrigation. The study was carried out on two watersheds in Burkina Faso, Kierma and Mogtedo. The spatiotemporal analysis of piezometric and SWRs level records coupled with physico-chemical analyses of water was used to characterize exchanges between SWRs and groundwater. The regional groundwater recharge at the scale of the watersheds was assessed. At the SWRs scale, a water balance methodology was developed and used to estimate focused recharge. The results show that SWRs interact almost continuously with groundwater and contribute focused recharge. The magnitude of this recharge is a function of the geological context and the sediment texture of the SWRs. It is estimated at 5 mm/day in Kierma and 4 mm/day in Mogtédo. These values are higher than the natural recharge estimated at 0.2 mm/day in Kierma and 0.1 mm/day in Mogtédo. Additionally, the values of hydraulic conductivity are between 0.01 and 2 m/day in Kierma and between 1 × 10−4 and 0.2 m/day in Mogtédo. These conductivities could allow pumping in large-diameter hand-dug wells with a significant yield between 0.5 and 120 m3 /day in Kierma and between 0 and 10 m3 /day in Mogtédo to palliate the early drying up of the SWRs. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.

Research center :

UEE - Urban and Environmental Engineering - ULiège

Disciplines :

Geological, petroleum & mining engineering

Author, co-author :

Bambara, Apolline ; Université de Liège - ULiège > UEE

Orban, Philippe ; Université de Liège - ULiège > Département ArGEnCo > Hydrogéologie & Géologie de l'environnement

Ouedraogo, I.; Ecole Supérieure d’Ingéninerie (ESI), University of Fada N’Gourma, BP 54, Fada N’Gourma, Burkina Faso

Hallot, Eric ; Université de Liège - ULiège > Département de géographie > Département de géographie

Guyon, F.; Non-Governmental Organization: Join For Water Benin, Benin

Zangré, A.; Ministry in Charge of Agriculture and Irrigation, 03 BP 7005, Ouaga, 2000, Burkina Faso

Brouyère, Serge ; Université de Liège - ULiège > Département ArGEnCo > Hydrogéologie & Géologie de l'environnement

Language :

English

Title :

Quantifying focused groundwater recharge induced by irrigation surface water reservoirs in crystalline basement areas for complementary irrigation

Publication date :

October 2020

Journal title :

Water

eISSN :

2073-4441

Publisher :

MDPI AG

Volume :

Issue :

Pages :

1-23

Peer reviewed :

Peer reviewed

Name of the research project :

Caractérisation des conditions hydrogéologiques des nappes alluviales en amont des retenues d'eau d'irrigation

Funders :

WBI - Wallonie-Bruxelles International [BE]

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Bibliography

Jalloh, A.; Faye, M.D.; Roy-Macauley, H.; Sérémé, P.; Zougmoré, R.; Thomas, T.S.; Nelson, G.C. Aperçu. In L’agriculture Ouest-Africaine et le Changement Climatique; Jalloh, A., Nelson, G.C., Thomas, T.S., Zougmoré, R., Roy-Macauley, H., Eds.; International Food Policy Research Institute: Washington, DC, USA, 2017; pp. 1–36. ISBN 978-0-89629-871-2.
Schmidhuber, J.; Tubiello, F.N. Food security under climate change. Proc. Natl. Acad. Sci. USA 2007, 6, 10–13. [CrossRef]
Gizaw, M.S.; Gan, T.Y. Impact of climate change and El Niño episodes on droughts in sub-Saharan Africa. Clim. Dyn. 2017, 49, 665–682. [CrossRef]
Descroix, L.; Genthon, P.; Peugeot, C.; Mahé, G.; Abdou, M.; Vandervaere, J.-P.; Mamadou, I.; Tanimoun, B.; Amadou, I.; Galle, S. Paradoxes et contrastes en Afrique de l’Ouest: Impacts climatiques et anthropiques sur les écoulements. Géologues 2015, 187, 47–52.
Serdeczny, O.; Adams, S.; Baarsch, F.; Coumou, D.; Robinson, A.; Hare, W.; Schaeffer, M.; Perrette, M.; Reinhardt, J. Climate change impacts in Sub-Saharan Africa: From physical changes to their social repercussions. Reg. Environ. Chang. 2017, 17, 1585–1600. [CrossRef]
Zougmoré, F.; Damiba, L.; D’Haen, S.; Dayamba, S.D. État Des Lieux Des Connaissances Scientifiques Sur Les Changements Climatiques Pour Les Secteurs Des Ressources En Eau, De L’Agriculture Et De La Zone Côtière; Climate Analytics: Berlin, Germany, 2019.
Mérino, M. Insécurité alimentaire en Afrique subsaharienne. Fond. Pour la Rech. Strat. 2009, 212, 1–9.
Diarra, A.; Barbier, B.; Yacouba, H. Adaptation de l’agriculture sahélienne aux changements climatiques: Une approche par la modélisation stochastique. Sci. Chang. Planétaires/Sécheresse 2013, 24, 57–63.
Morris, J.; Barron, J. Agricultural Water Management Technology Expansion and Impact on Crop Yields in Northern Burkina Faso (1980-2010): A Review. CGIAR Chall. Progr. Water Food 2014, 10, 44.
Mul, M.; Obuobie, E.; Appoh, R.; Kankam-Yeboah, K.; Bekoe-Obeng, E.; Amisigo, B.; Logah, F.Y.; Ghansah, B.; McCartney, M. Water Resources Assessment of the Volta River Basin; International Water Management Institute: Colombo, Sri Lanka, 2015.
Woodhouse, P.; Veldwisch, G.J.; Venot, J.P.; Brockington, D.; Komakech, H.; Manjichi, Â. African farmer-led irrigation development: Re-framing agricultural policy and investment? J. Peasant Stud. 2017, 44, 213–233. [CrossRef]
Venot, J.P.; de Fraiture, C.; Acheampong, E.N. Revisiting Dominant Notions: A Review of Costs, Performance and Institutions of Small Reservoirs in Sub-Saharan Africa; International Water Management Institute: Colombo, Sri Lanka, 2012.
Ayantunde, A.A.; Cofie, O.; Barron, J. Multiple uses of small reservoirs in crop-livestock agro-ecosystems of Volta basin: Implications for livestock management. Agric. Water Manag. 2018, 204, 81–90. [CrossRef]
Nikkels, M.J.; van Oel, P.R.; Meinke, H.; Hellegers, P.J.G.J. Challenges in assessing the regional feasibility of local water storage. Water Int. 2019, 44, 854–870. [CrossRef]
Marlet, S.; Sanogo, S.; Keita, M. Evaluation Finale du ”Projet de Réduction de la Vulnérabilité des Petits Barrages aux Changements Climatiques (PRVPB-CC)”; Appraisal Report: Ouagadougou, Burkina Faso, 2017.
Ogilvie, A.; Riaux, J.; Massuel, S.; Mulligan, M.; Belaud, G.; Le Goulven, P.; Calvez, R. Socio-hydrological drivers of agricultural water use in small reservoirs. Agric. Water Manag. 2019, 218, 17–29. [CrossRef]
Acheampong, E.N.; Ozor, N.; Sekyi-annan, E. Development of small dams and their impact on livelihoods: Cases from northern Ghana. Afr. J. Agric. Res. 2014, 9, 1867–1877. [CrossRef]
Fowe, T.; Karambiri, H.; Paturel, J.E.; Poussin, J.C.; Cecchi, P. Water balance of small reservoirs in the volta basin: A case study of boura reservoir in burkina faso. Agric. Water Manag. 2015, 152, 99–109. [CrossRef]
Habets, F.; Molenat, J.; Carluer, N.; Douez, O.; Leenhardt, D. Cumulative impact of small reservoirs: A review of estimations and methods. EGU Gen. Assem. Conf. Abstr. 2018, 20, 14758.
Lacombe, G. Evolution et Usages de la Ressource en eau Dans un Bassin Versant Amenage Semi-aride. Ph.D. Thesis, Montpellier 2 University, Montpellier, France, 24 October 2007.
Singh, A.; Panda, S.N.; Saxena, C.K.; Verma, C.L.; Uzokwe, V.N.E.; Krause, P.; Gupta, S.K. Optimization modeling for conjunctive use planning of surface water and groundwater for irrigation. J. Irrig. Drain. Eng. 2016, 142, 04015060. [CrossRef]
Singh, D.; Flook, S.; Pandey, S.; Erasmus, D.; Foster, L.; Phillipson, K.; Smallacombe, J.; Khor, J.; Lowry, S. Improved characterisation of unmetered stock and domestic groundwater use in the Surat and Southern Bowen basins of the Great Artesian Basin (Australia). Hydrogeol. J. 2020, 28, 413–426. [CrossRef]
Ammar, S.B.; Jeribi, L.; Favreau, G.; Zouari, K.; Leduc, C.; Oi, M.; M’barek, J.; Beji, R. Évolution de la recharge de la nappe phréatique de la plaine de Kairouan (Tunisie centrale) déduite de l’analyse géochimique. Sécheresse 2019, 20, 087–095. [CrossRef]
Biswas, H.; Sena, D.R.; Kumar, G.; Lakaria, B.L.; Raizada, A.; Kumar, S.; Mishra, P.K. Effect of water storage structures on groundwater recharge in India. Groundw. Sustain. Dev. 2017, 4, 49–56. [CrossRef]
Kumar, S.; Bhadra, B.K.; Paliwal, R. Evaluating the impact of artificial groundwater recharge structures using geo-spatial techniques in the hard-rock terrain of Rajasthan, India. Environ. Earth Sci. 2017, 76, 613. [CrossRef]
Song, J.H.; Kang, M.S.; Song, I.; Jun, S.M. Water balance in irrigation reservoirs considering flood control and irrigation efficiency variation. J. Irrig. Drain. Eng. 2016, 142, 04016003. [CrossRef]
Andreini, M.; Schuetz, T.; Senzanje, A.; Andah, W.; Cecchi, P.; Bolee, E.; De Giesen, V.; Kemp-benedikt, E.; Liebe, J. CPWF Project Number 46 Report: Small Multi-Purpose Reservoir Ensemble Planning; Program on Water and Food Project Report Series: Montpellier, France, 2009.
Yiasoumi, B. Leaking Farm Dams. In NSW Dep. Prim. Ind.; NSW Department of Primary Industries: New South Wales, Australian, 2004; p. 6.
Abdalla, O.A.E.; Al-Rawahi, A.S. Groundwater recharge dams in arid areas as tools for aquifer replenishment and mitigating seawater intrusion: Example of AlKhod, Oman. Environ. Earth Sci. 2013, 69, 1951–1962. [CrossRef]
Kuroda, K.; Hayashi, T.; Do, A.T.; Canh, V.D.; Nga, T.T.V.; Funabiki, A.; Takizawa, S. Recharge des eaux souterraines dans des régions suburbaines de Hanoï, Vietnam: Effet de la diminution des niveaux des masses d’eaux de surface et des changements d’occupation du sol. Hydrogeol. J. 2017, 25, 727–742. [CrossRef]
Sharda, V.N.; Kurothe, R.S.; Sena, D.R.; Pande, V.C.; Tiwari, S.P. Estimation of groundwater recharge from water storage structures in a semi-arid climate of India. J. Hydrol. 2006, 329, 224–243. [CrossRef]
Ali, S.; Ghosh, N.C. Integrated modelling of potential recharge in small recharge ponds. Arab. J. Geosci. 2019, 12. [CrossRef]
Jasrotia, A.S.; Kumar, R.; Taloor, A.K.; Saraf, A.K. Artificial recharge to groundwater using geospatial and groundwater modelling techniques in North Western Himalaya, India. Arab. J. Geosci. 2019, 12. [CrossRef]
Mohammadzadeh-Habili, J.; Khalili, D. Assessment of Artificial Recharge Dams and Improvement of Their Groundwater-Recharge Capacity. J. Hydrol. Eng. 2020, 25. [CrossRef]
Boisson, A.; Baïsset, M.; Alazard, M.; Perrin, J.; Villesseche, D.; Dewandel, B.; Kloppmann, W.; Chandra, S.; Picot-Colbeaux, G.; Sarah, S.; et al. Comparison of surface and groundwater balance approaches in the evaluation of managed aquifer recharge structures: Case of a percolation tank in a crystalline aquifer in India. J. Hydrol. 2014, 519, 1620–1633. [CrossRef]
Parimalarenganayaki, S.; Elango, L. Assessment of effect of recharge from a check dam as a method of Managed Aquifer Recharge by hydrogeological investigations. Environ. Earth Sci. 2015, 73, 5349–5361. [CrossRef]
Guyon, F.; Hallot, E.; DE Thysebaert, D.; Diarra, B.G.; Roamba, J.; Zangré, A. Résultat du bilan hydrologique de la retenue d’eau d’irrigation de Kierma. In Proceedings of the Atelier de Capitalisation des Résultats et Acquis du PADI, Ouagadougou, Burkina Faso, 14–15 November 2016.
Guyon, F.; Hallot, E.; DE Thysebaert, D.; Diarra, B.G.; Roamba, J.; Zangré, A. Résultat du bilan hydrologique de la retenue d’eau d’irrigation de Mogtédo. In Proceedings of the Atelier de Capitalisation des Résultats et Acquis du PADI, Ouagadougou, Burkina Faso, 14–15 November 2016; p. 9.
Thornthwaite, C.W. An approach toward a rational classification of climate. Geograph. Rev. 1948, 38, 55–94. [CrossRef]
Cecchi, P.; Forkuor, G.; Cofie, O.; Lalanne, F.; Poussin, J.C.; Jamin, J.Y. Small reservoirs, landscape changes and water quality in sub-Saharan West Africa. Water 2020, 12, 1967. [CrossRef]
Padonou, M.M.N.; Sarr, M.P. Contribution de la Télédétection et du Système d’information Géographique (SIG) a l’amélioration de la gestion des eaux de surface dans un bassin versant: Cas du barrage de Mogtedo au Burkina Faso. In Proceedings of the Journées d’Animation Scientifique (JAS09) de l’AUF Alger, Algers, Algeria, 8–11 November 2009; pp. 1–7.
Guyon, F.; Hallot, E.; DE Thysebaert, D.; Diarra, B.G.; Roamba, J.; Zangré, B.V.A. Pratiques d’irrigation autour des retenues de Kierma, Mogtedo et Wedbila. In Proceedings of the Atelier de capitalisation des résultats et Acquis du PADI, Ouagadougou, Burkina Faso, 14–15 November 2016.
Hottin, G.; Ouedraogo, O. Notice explicative de la carte Géologique à 1/1000000 de la République de Haute Volta. BRGM 1975.
Koussoubé, Y.; Upton, K.; O Dochartaigh, B.; Bellwood-Howard, I.; Zeggan, A. Africa Groundwater Atlas; UPGro: Ghana, African, 2016; pp. 1–4.
Savadogo, N. Géologie et Hydrogéologie du Socle Cristallin de Haute-Volta: Étude régionale du Bassin Versant de la Sissili. Ph.D. Thesis, Université Scientifique et Médicale de Grenoble, Grenoble, France, 1984.
BUMIGEB. BUMIGEB Données Hydrogéologiques des Dégrés Carrés de Ouagadougou et de Pô; BUMIGEB: Ouagadougou, Burkina Faso, 2018.
Yaméogo, D. Hydrogéologie des Formations Fissurées de la Partie sud du Plateau Mossi entre le Nazino et le Nakambe (région de Kombissiri-Manga) Burkina Faso. Ph.D. Thesis, Université Scientifique et Médicale de Grenoble, Grenoble, France, 1988.
Abdou Babaye, M.S. Evaluation des Ressources en eau Souterraine dans le Bassin du Dargol (Liptako-Niger). Ph.D. Thesis, Université de Liège, Liège, Belgique, 20 December 2012.
Pieyns, S.A.; Ouedraogo, F.N.; Kagambega, Z.; Kabore, E. Amélioration de la Connaissance et de la Gestion des eaux au Burkina Faso-Rapport Evaluation des Ressources en Eau et des Demandes Sectorielles et Bilan Besoins-Ressources; Rapport: Burkina Faso, 2017.
Chung, I.M.; Sophocleous, M.A.; Mitiku, D.B.; Kim, N.W. Estimating groundwater recharge in the humid and semi-arid African regions: Review. Geosci. J. 2016, 20, 731–744. [CrossRef]
Philip, J.R. Theory of Infiltration. Adv. Water Resour. 1969, 5, 215–296.
Dassargues, A. Hydrogeology: Groundwater Science and Engineering; CRC Press: Cleveland, OH, USA, 2018; ISBN 0429894406.
Allen, R.G.; Pereira, L.S.; Smith, M.; Raes, D.; Wright, J.L. FAO-56 Dual Crop Coefficient Method for Estimating Evaporation from Soil and Application Extensions. J. Irrig. Drain. Eng. 2005, 131, 2–13. [CrossRef]
Dieng, N.M. Etude de la Relation Eaux de Surface-eaux Souterraines dans un Contexte de Changements Climatiques Dans la zone sud du Bassin du Saloum (Sénégal). Ph.D. Thesis, Université de Liège, Liège, Belgique, 24 October 2017.
Cecchi, P. Les Petits Barrages au Burkina Faso: Un vecteur du changement social et de mutations des réalités rurales. Pre Forum Mond. L’eau 2006, 12, 1–12.
Mahé, G.; Diello, P.; Paturel, J.; Barbier, B.; Dezetter, A.; Dieulin, C.; Rouché, N. Baisse des pluies et augmentation des écoulements au Sahel: Impact climatique et anthropique sur les écoulements du Nakambe au Burkina Faso. Sécheresse 2010, 21, 330–332.
Kohonen, T. Matlab Implementations and Aplications of Self-organizing Map; Unigrafia Oy: Helsinki, Finland, 2014; ISBN 9789526036786.
Döll, P.; Kiedler, K. Global-scale modeling of groundwater recharge. Hydrol. Earth Syst. Sci. 2008, 12, 863–885. [CrossRef]
Cuthbert, M.O.; Taylor, R.G.; Favreau, G.; Todd, M.C.; Shamsudduha, M.; Villholth, K.G.; MacDonald, A.M.; Scanlon, B.R.; Kotchoni, D.O.V.; Vouillamoz, J.-M.; et al. Observed controls on resilience of groundwater to climate variability in sub-Saharan Africa. Nature 2019, 572, 230–234. [CrossRef]
Orban, P.; Derouane, J.; Compaore, N.F.; Bambara, A.; Briers, P.; Brouyère, S. Renforcement des Capacités de la Direction Générale des Aménagements et du Développement de l’Irrigation et des Directions Régionales de l’Agriculture et de l’Hydraulique des Cascades, des Hauts bassins et du Plateau Central à Concevoir et à Mettre en œuv; Wallonie Bruxelles International: Bruxelles, Belgium, 2016.
Orban, P.; Derouane, J.; Compaoré, N.F.; Bambara, A.; Briers, P.; Sprumont, C.; Mahamadi, Z.; Zangre, A.; Brouyère, S. Renforcement des capacités de la Direction Générale des Aménagements et du Développement de l’Irrigation et des Directions Régionales de l’Agriculture et de l’Hydraulique des Cascades, des Hauts bassins et du Plateau Central à Concevoir et à Mettre en œuv; Wallonie Bruxelles International: Bruxelles, Belgium, 2017.
Orban, P.; Bambara, A.; Grommet, A.; Zoundi, M.; Derouane, J.; Zangré, A.; Brouyère, S. Renforcement des capacités de la Direction Générale des Aménagements et du Développement de l’Irrigation et des Directions Régionales de l’Agriculture et de l’Hydraulique des Cascades, des Hauts bassins et du Plateau Central à Concevoir et à Mettre en œuv; Wallonie Bruxelles International: Bruxelles, Belgium, 2018.
Rodier, J.; Legube, B. L’Analyse De L’Eau Contrôle Et Interprétation; Dunod: Paris, France, 2009; pp. 1–1600.
Haas, S. De Hydrogeology and Siting of Micro-dams Around Léo, Burkina Faso; Mission Report: Burkina Faso, 2010.
Winter, T.C.; Harvey, J.W.; Franke, O.L.; Alley, W.M. Ground Water and Surface Water—A single Resource—U.S. Geological Survey Circular 1139. USGS Publ. 1998, Circular 1, 79.
Brodie, R.S.; Sundaram, B.; Tottenham, R.; Hostetler, S. An overview of tools for assessing groundwater-surface water connectivity. Bur. Rural Sci. 2007, 131.
Oyarzún, R.; Zambra, S.; Maturana, H.; Oyarzún, J.; Aguirre, E.; Kretschmer, N. Chemical and isotopic assessment of surface water–shallow groundwater interaction in the arid Grande river basin, North-Central Chile. Hydrol. Sci. J. 2016, 61, 2193–2204. [CrossRef]
Piper, A.M. A graphic procedure in the geochemical interpretation of water-analyses. Eos, Trans. Am. Geophys. Union 1944, 25, 914–928. [CrossRef]
Baskaran, S.; Ransley, T.; Brodie, R.S.; Baker, P. Investigating groundwater-river interactions using environmental tracers. Aust. J. Earth Sci. 2009, 56, 13–19. [CrossRef]
Sprumont, C. Caractérisation des conditions hydrogéologiques au voisinage de petites retenues d’eau d’irrigation (Mogtédo, Burkina Faso). Master’s Thesis, Université de Liège, Liège, Belgium, 2016.
Abid, K.; Trabelsi, R.; Zouari, K.; Abidi, B. Caractérisation hydrogéochimique de la nappe du continental intercalaire (sud tunisien). Hydrol. Sci. 2009, 54, 16. [CrossRef]
Gning, A.A.; Orban, P.; Gesels, J.; Ngom, F.D.; Dassargues, A.; Malou, R.; Brouyère, S. Factors controlling the evolution of groundwater dynamics and chemistry in the Senegal River Delta. J. Hydrol. Reg. Stud. 2017, 10, 133–144. [CrossRef]
Lewandowski, J.; Meinikmann, K.; Krause, S. Groundwater—Surface Water Interactions. Groundwater—Surface Water Interactions. Water 2020, 296, 15–18.
Oblinger, J.A.; Moysey, S.M.J.; Ravindrinath, R.; Guha, C. A pragmatic method for estimating seepage losses for small reservoirs with application in rural India. J. Hydrol. 2010, 385, 230–237. [CrossRef]
Boisson, A.; Villesseche, D.; Baisset, M.; Perrin, J.; Viossanges, M.; Kloppmann, W.; Chandra, S.; Dewandel, B.; Picot-Colbeaux, G.; Rangarajan, R.; et al. Questioning the impact and sustainability of percolation tanks as aquifer recharge structures in semi-arid crystalline context. Environ. Earth Sci. 2015, 73, 7711–7721. [CrossRef]
Parimalarenganayaki, S.; Elango, L. Quantification of groundwater recharge and river bed clogging by daily water level measurements in a check dam. Arab. J. Geosci. 2018, 11. [CrossRef]
Chabi, A. Assessment of Water Balance in the Ilauko Reservoir of the Ouémé at Savè Catchment (Benin, West Africa). Hydrology 2019, 7, 15. [CrossRef]
Guyon, F.; Hallot, E.; De Thysebaert, D.; Galley, D.B.; Joel, R.; Zangre, A. Estimation des bilans Hydrologiques des Retenues d’ eau d’irrigation—Méthodologie; Rapport PADI: Burkina Faso, 2016.
Pouyaud, B. Contribution à L’évaluation de L’évaporation de Nappes d’eau Libre en Climat Tropical sec; ORSTOM: Paris, France, 1986; ISBN 2709908255.
Althoff, D.; Rodrigues, L.N.; Silva, D.D. da Evaluating evaporation methods for estimating small reservoir water surface evaporation in the Brazilian savannah. Water 2019, 11, 1942. [CrossRef]
Zhao, G.; Gao, H. Estimating reservoir evaporation losses for the United States: Fusing remote sensing and modeling approaches. Remote Sens. Environ. 2019, 226, 109–124. [CrossRef]
Winter, T.C. Uncertainties in Estimating the Water Balance of Lakes. JAWRA J. Am. Water Resour. Assoc. 1981, 17, 82–115. [CrossRef]
Sacks, L.; Swancar, A.; Lee, T.M. Estimating Ground-Water Exchange with Lakes Using Water-Budget and Chemical Mass-Balance Approaches for Ten Lakes in Ridge Areas of Polk and Highlands Counties, Florida. Water-Resour. Investig. Rep. 1998, 98, 4133. [CrossRef]
Trask, J.C.; Fogg, G.E.; Puente, C.E. Resolving hydrologic water balances through a novel error analysis approach, with application to the Tahoe basin. J. Hydrol. 2017, 546, 326–340. [CrossRef]
Lee, T.M.; Swancar, A. Influence of Evaporation, Ground Water, and Uncertainty in the Hydrologic Budget of Lake Lucerne, a Seepage Lake in Polk County, Florida; U.S. Geol. Surv. Water-supply; US Government Printing Office: Washington, DC, USA, 1996; p. 61.
Motz, L.H.; Sousa, G.D.; Annable, M.D. Water budget and vertical conductance for Lowry (Sand Hill) lake in north-central Florida, USA. J. Hydrol. 2001, 250, 134–148. [CrossRef]
Herschy, R.W. The Magnitude of Errors at Flow Measurement Stations; Water Resources Board: Colombo, Sri Lanka, 1971.
Bouteffeha, M.; Dages, C.; Bouhlila, R.; Molenat, J. A water balance approach for quantifying subsurface exchange fluxes and associated errors in hill reservoirs in semiarid regions. Hydrol. Process. 2015, 29, 1861–1872. [CrossRef]
Dahlke, H.E.; LaHue, G.T.; Mautner, M.R.L.; Murphy, N.P.; Patterson, N.K.; Waterhouse, H.; Yang, F.; Foglia, L. Managed Aquifer Recharge as a Tool to Enhance Sustainable Groundwater Management in California: Examples From Field and Modeling Studies. In Advances in Chemical Pollution, Environmental Management and Protection; Elsevier: Amsterdam, The Netherlands, 2018; Volume 3, pp. 215–275. ISBN 9780128142998.
Bouwer, H.; Rice, R.C. A slug test for determining hydraulic conductivity of unconfined aquifers with completely or partially penetrating wells. Water Resour. Res. 1976, 12, 423–428. [CrossRef]
Duffield, G.M. AQTESOLV for Windows Version 4.5 User’s Guide; HydroSOLVE: Reston, VA, USA, 2007; pp. 1–530.
Bear, J. Dynamics of Fluids in Porous Media; Eisevier: New York, NY, USA, 1972; pp. 1–783.
Fussi, F.F.; Fumagalli, L.; Fava, F.; Di Mauro, B.; Kane, C.H.; Niang, M.; Wade, S.; Hamidou, B.; Colombo, R.; Bonomi, T. Classifying zones of suitability for manual drilling using textural and hydraulic parameters of shallow aquifers: A case study in northwestern Senegal. Hydrogeol. J. 2017, 25, 2263–2279. [CrossRef] [PubMed]
Gowing, J.; Walker, D.; Parkin, G.; Forsythe, N.; Haile, A.T.; Ayenew, D.A. Can shallow groundwater sustain small-scale irrigated agriculture in sub-Saharan Africa? Evidence from N-W Ethiopia. Groundw. Sustain. Dev. 2020, 10, 100290. [CrossRef]
Barker, J.A.; Herbert, R. Nomograms for the analysis of recovery tests on large-diameter wells. Q. J. Eng. Geol. 1989, 22, 151–158. [CrossRef]
Schoeller, H. Zone et rayon d’appel, dÉbits spÉcifiques des forages et puits. calcul des constantes des couches aquifères et de la longueur du front d’emprunt. Int. Assoc. Sci. Hydrol. Bull. 1956, 1, 24–41. [CrossRef]
Koussoubé, Y. Hydrogéologie en milieu de socle cristallin du Burkina Faso. Cas du bassin versant du bas-fond de Bidi (province du Yatenga). Univ. Cheikh Anta Diop Dakar 1996, 1, 263.