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Sustainable Water Resources Management

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01.12.2022 | Original Article

Groundwater prospective mapping using remote sensing and GIS techniques: the case of Meki watershed in Central Rift Valley, Ethiopia

verfasst von: Diriba Worku Doyo, Sirak Tekleab Gebrekristos, Ayalew Shura Kasa, Samuel Dagalo Hatiye

Erschienen in: Sustainable Water Resources Management | Ausgabe 6/2022

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Abstract

Groundwater prospective mapping has several functions, including irrigation water supply, domestic and industrial water uses. This study aimed to map prospective groundwater zones in the Meki watershed, Ethiopia. Climate, physiographic, geologic, and satellite image data were used as factors for groundwater mapping. Thematic maps of rainfall, land use/land cover, soil, drainage density, slope, geomorphology, elevation, and geology were analyzed using ArcGIS 10.4. Land use/land cover classification was based on the 2016 satellite images. The PCI Geomatica 10.3 package was used to produce the lineament map, and eventually, the lineament density map was produced using ArcGIS 10.4. We used the Analytical Hierarchical Process (AHP) tool to prioritize the different factors affecting the groundwater condition of the area. The reclassified thematic layers of the factors were overlaid using weighted linear combination analysis in Arc GIS 10.4. The result depicted that geomorphology, geology, and land slope shared a higher weight having 26%, 20%, and 18%, respectively. Small areal coverage is accounted for by very high and low zones of groundwater potential, and a significant portion of the watershed falls in high (30% of the watershed) to moderate (35% of the watershed) groundwater potential zones indicating good groundwater prospects in the region. The produced groundwater potential map was validated using data from groundwater well inventories. According to the groundwater flow vector, groundwater flows primarily from the northwest to the southeast. Therefore, this study's results could help locate potential groundwater well sites for various purposes in the Meki watershed, Ethiopia.

Vorheriger Artikel Groundwater potential mapping using integrations of remote sensing and analytical hierarchy process methods in Ataye-watershed, Middle Awash Basin, Ethiopia

Nächster Artikel Modeling the spatial pattern of potential groundwater zone using MCDM-AHP and geospatial technique in sub-tropical plain region: a case study of Islampur sub-division, West Bengal, India

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Abdelkareem OEA, Elamin HMA, Eltahir MES, Adam HE, Elhaja ME, Rahamtalla AM, Babatunde O, Elmar C (2017) Accuracy assessment of land use land cover in Umabdalla Natural Reserved Forest, South Kordofan, Sudan. Int J Agric Environ Sci 3(1):5–9

Abraham A, Das A, Tom A, Sasi A (2018) Delineation of groundwater potential zones in Manimala Watershed, India using GIS. Int J Water Resour Pollut Stud 3(2):1–11

Adeyeye OA, Ikpokonte EA, Arabi SA (2018) GIS-based groundwater potential mapping within Dengi area, North Central Nigeria. Egypt J Remote Sens Space Sci 1:1–7. https://doi.org/10.1016/j.ejrs.2018.04.003CrossRef

Adiat KAN, Nawawi MNM, Abdullah K (2012) Assessing the accuracy of GIS-based elementary multi criteria decision analysis as a spatial prediction tool—a case of predicting potential zones of sustainable groundwater resources. J Hydrol 440:75–89CrossRef

Allafta H, Opp C, Patra S (2021) Identification of groundwater potential zones using remote sensing and GIS techniques: a case study of the Shatt Al-Arab Basin. Remote Sens 13:112. https://doi.org/10.3390/rs13010112CrossRef

Al-Manmi DAM, Rauf LF (2016) Groundwater potential mapping using remote sensing and GIS-based, in Halabja City, Kurdistan, Iraq. Arab J Geosci 9(5):1–13CrossRef

Al-shabeeb ARR (2015) A modified analytical hierarchy process method to select sites for groundwater recharge in Jordan. Doctoral dissertation, University of Leicester, p 2014

Alshehri F, Mohamed S, Sita K, Essam K, Saleh A, Hassan A, Hossein S, Nile S (2020) Mapping the distribution of shallow groundwater occurrences using remote sensing-based statistical modeling over Southwest Saudi Arabia. J Remote Sens 4:1–22

Anbazhagan S, Jothibasu A (2016) Geoinformatics in groundwater potential mapping and sustainable development: a case study from southern India. Hydrol Sci J 61(6):1109–1123CrossRef

Anbazhagan S, Balamurugan G, Biswal TK (2011) Remote sensing in delineating deep fracture aquifer zones. Geoinformatics in applied geomorphology. CRC Press: Taylor and Francis, New York, pp 205–229CrossRef

Anderson JR (1976) A land use and land cover classification system for use with remote sensor data, vol 964. US Government Printing Office, Washington DC

Andualem TG, Demeke GG (2019) Groundwater potential assessment using GIS and remote sensing: study of guna Tana landscape, Upper Blue Nile Basin, Ethiopia. J Hydrol Reg Stud 24(1006102):2019

Argaz A, Ouahman B, Darkaoui A, Bikhtar H, Yabsa K, Laghzal A (2019) Application of remote sensing techniques and GIS-multicriteria decision analysis for groundwater potential mapping in Souss Watershed, Morocco. J Mater Environ Sci 10(5):411–421

Arkoprovo B, Adarsa J, Prakash SS (2012) Delineation of groundwater potential zones using satellite remote sensing and geographic information system techniques : a case study from Ganjam district, Orissa, India. Res J Recent Sci 1(9):59–66

Arunbose S, Srinivas Y, Rajkumar S, Nair NC, Kaliraj S (2021) Remote sensing, GIS and AHP techniques based investigation of groundwater potential zones in the Karumeniyar river basin, Tamil Nadu, southern India. Groundw Sustain Dev 14:100586CrossRef

Awawdeh M, Obeidat M, Al-Mohammad M et al (2014) Integrated GIS and remote sensing for mapping groundwater potentiality in the Tulul al Ashaqif, Northeast Jordan. Arab J Geosci 7:2377–2392. https://doi.org/10.1007/s12517-013-0964-8CrossRef

Ayalew DW (2018) Theoretical and empirical review of Ethiopian water resource potentials, challenges and future development opportunities. Int J Waste Resour 8(4):85–856. https://doi.org/10.4172/2252-5211.1000353CrossRef

Berhanu KG, Hatiye SD (2020) Identification of groundwater potential zones using proxy data: case study of Megech Watershed, Ethiopia. J Hydrol Reg Stud 28:100676. https://doi.org/10.1016/j.ejrh.2020.100676CrossRef

Bonsor HC, MacDonald AM (2011) An initial estimate of depth to groundwater across Africa. Groundwater Science Programme. Open Report OR/11/067, p 26

Chernet T (1982) Hydrogeology of the lakes region, Ethiopia. Ethiopian Geological Survey Memoir, 7, p 106

Choudhury PR (1999) Integrated remote sensing and GIS techniques for groundwater studies in part of Betwa basin. PhD thesis (unpublished), Department of Earth Sciences, University of Roorkee

Edet AE, Okereke CS, Teme SC, Esu EO (1998) Application of remote-sensing data to groundwater exploration: a case study of the Cross River State, southeastern Nigeria. Hydrogeol J 6(3):394–404CrossRef

Fashae OA, Tijani MN, Talabi AO, Adedeji OI (2014) Delineation of groundwater potential zones in the crystalline basement terrain of SW-Nigeria: an integrated GIS and remote sensing approach. Appl Water Sci 4(1):19–38. https://doi.org/10.1007/s13201-013-0127-9CrossRef

Fenta AA, Kifle A, Gebreyohannes T, Gebrerufael HA (2015) Spatial analysis of groundwater potential using remote sensing and GIS-based multi-criteria evaluation in Raya Valley, northern Ethiopia. Hydrogeol J 23:195. https://doi.org/10.1007/s10040-014-1198-xCrossRef

Fetter CW (1980) Applied hydrogeology. CE Merrill, Columbus

Gintamo TT (2015) Ground water potential evaluation based on integrated GIS and remote sensing techniques, in bilate river catchment: South Rift Valley of Ethiopia. Am Sci Res J Eng Technol Sci (ASRJETS) 10(1):85–120

Gouri SB, Sailesh S, Dilip Kumar P, Babita P (2012) Assessment of groundwater potential zone in Paschim Medinipur District, West Bengal—a meso-scale study using GIS and remote sensing approach. Assessment 2(5):41–59

Gyeltshen S, Tran TV, Gunda GKT, Kannaujiya S, Chatterjee RS, Champatiray PK (2019) Groundwater potential zones using a combination of geospatial technology and geophysical approach: case study in Dehradun, India. Hydrol Sci J. https://doi.org/10.1080/02626667.2019.1688334CrossRef

Kassa N (2007) Groundwater resources evaluation and management in Dugda Woreda, Central Rift Valley, Ethiopia. Doctoral dissertation, Addis Ababa Universty. p 129

Khosravi K, Panahi M, Tien Bui D (2018) Spatial prediction of groundwater spring potential mapping based on an adaptive neuro-fuzzy inference system and metaheuristic optimization. Hydrol Earth Syst Sci 22(9):4771–4792CrossRef

Krishnamurthy JN, Venkatesa K, Jayaraman V, Manivel M (1996) An approach to demarcate ground water potential zones through remote sensing and geographical information system. Int J Remote Sens 17:1867–1884CrossRef

Kumar PK, Gopinath G, Seralathan P (2007) Application of remote sensing and GIS for the demarcation of groundwater potential zones of a river basin in Kerala, southwest coast of India. Int J Remote Sens 28(24):5583–5601CrossRef

Kumar P, Herath S, Avtar R, Takeuchi K (2016) Mapping of groundwater potential zones in Killinochi area, Sri Lanka, using GIS and remote sensing techniques. Sustain Water Resour Manag 2(4):419–430. https://doi.org/10.1007/s40899-016-0072-5CrossRef

Lakshmi SV, Reddy YK (2018) Identification of groundwater potential zones using GIS and remote sensing. Pure Appl Math 17:3195–3210

Magesh NS, Chandrasekar N, Soundranayagam JP (2012) Delineation of groundwater potential zones in Theni district, Tamil Nadu, using remote sensing, GIS and MIF techniques. Geosci Front 3(2):189–196. https://doi.org/10.1016/j.gsf.2011.10.007CrossRef

Mogaji KA, Aboyeji OS, Omosuyi GO (2011) Mapping of lineaments for groundwater targeting in the basement complex region of Ondo State, Nigeria, using remote sensing and geographic information system (GIS) techniques. Int J Water Resour Environ Eng 37:150–160

Otutu OJ (2010) Determination of groundwater flow direction at Emu and Ogume kingdoms/Nigeria. Int J Res 5:310–314

Rajaveni SP, Brindha K, Elango L (2017) Geological and geomorphological controls on groundwater occurrence in a hard rock region. Appl Water Sci 7(3):1377–1389. https://doi.org/10.1007/s13201-015-0327-6CrossRef

Rahmati O, Nazari Samani A, Mahdavi M, Pourghasemi HR, Zeinivand H (2015) Groundwater potential mapping at Kurdistan region of Iran using analytic hierarchy process and GIS. Arab J Geosci 8(9):7059–7071. https://doi.org/10.1007/s12517-014-1668-4CrossRef

Ramu Mahalingam B, Vinay M (2010) Identification of ground water potential zones using GIS and Remote sensing Techniques: a case study of Mysore taluk–Karnataka. Int J Geomat Geosci 5(3):393–403

Rwanga SS, Ndambuki JM (2017) Accuracy assessment of land use/land cover classification using remote sensing and GIS. Int J Geosci 8(04):611CrossRef

Saaty TL (1980) The analytic hierarchy process: planning, priority setting, priority setting, resource allocation. McGraw-Hill, New York

Saaty TL (1990) How to make a decision: the analytic hierarchy process. Eur J Oper Res 48(1):9–26CrossRef

Saaty TL (2008) Decision making with the analytic hierarchy process. Int J Serv Sci 1(1):83–98

Saraf AK, Choudhury PR (1998) Integrated remote sensing and GIS for groundwater exploration and identification of artificial recharge sites. Int J Remote Sens 19(10):1825–1841CrossRef

Savita RS, Mittal HK, Satishkumar U, Singh PK, Yadav KK, Jain HK, Mathur SM, Sham D (2018) Delineation of groundwater potential zones using remote sensing and GIS techniques in Kanakanala Reservoir Subwatershed, Karnataka, India. Int J Curr Microbiol Appl Sci 7(01):273–288CrossRef

Schmoll O, Howard G, Chilton J, Chorus I (2006) Protecting groundwater for health: managing the quality of drinking-water sources. World Health Organization, Geneva

Singh SK, Zeddies M, Shankar U, Griffiths GA (2019) Potential groundwater recharge zones within New Zealand. Geosci Front 10(3):1065–1072. https://doi.org/10.1016/j.gsf.2018.05.018CrossRef

Singhal BBS, Gupta RP (2010) Applied hydrogeology of fractured rocks. Springer Science & Business Media, DordrechtCrossRef

Todd DK (1980) Ground water hydrology, 2nd edn. Wiley, New York

Todd DK, Mays LW (2005) Groundwater hydrology, 3rd edn. Wiley, New York

Vanum AH, Amare GN, Abdul-Aziz H (2017) Evaluation of groundwater potential using geospatial techniques. Appl Water Sci 7(5):2447–2461. https://doi.org/10.1007/s13201-016-0433-0CrossRef

Titel: Groundwater prospective mapping using remote sensing and GIS techniques: the case of Meki watershed in Central Rift Valley, Ethiopia
verfasst von: Diriba Worku Doyo
Sirak Tekleab Gebrekristos
Ayalew Shura Kasa
Samuel Dagalo Hatiye
Publikationsdatum: 01.12.2022
Verlag: Springer International Publishing
Erschienen in: Sustainable Water Resources Management / Ausgabe 6/2022
Print ISSN: 2363-5037
Elektronische ISSN: 2363-5045
DOI: https://doi.org/10.1007/s40899-022-00775-1

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