Tytuł artykułu
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Water scarcity and soil erosion are the main constraints small holder farmers are facing in Tigray, the northern most part of Ethiopia. Both very high and very low precipitation can cause a damage to agriculture which is the case in semi-arid regions like Tigray. While too little rainfall cannot support the growth of crops resulting in crop failure, the short but intense rainfall also causes a runoff thereby washing away essential soil nutrients. Installation of different micro/macro-catchment rainwater harvesting can address both water scarcity and soil erosion if they are properly designed prior to construction. This research was intended to develop a methodology for identifying suitable rainwater harvesting (rwh) sites by using weighted overlay analysis. It also utilizes Ahp (analytical hierarchy process) as effective multi-criterion decision-making tool in eastern Tigray at Kilte Awlaelo district on an area of 1001 km2 . This method was chosen because it is simple to use, cost effective, flexible and widely adopted. Physical, hydrological, climate and socio-economic aspects were taken into account during criteria selection. The result indicated four suitability classes with 8.74% highly suitable areas (85.25 km2 ), 56% suitable areas (550.75 km2 ), 30.8% moderately suitable areas (303.2 km2 ) and 4.46% less suitable areas (43.87 km2 ). The produced rwh suitability map was also validated by both ground truth on google earth pro and a field trip to the study site. In situ and ex situ rwh including bench terraces, wells, and enclosure areas were identified during the field visit that verified the suitability model. Finally, depending on weight and scale of criteria and sub-criteria that matched to each identified suitable areas, different micro-catchment and macro-catchment techniques of water harvesting are recommended. This methodology can be utilized as decision-making tool for rwh practitioners, local and foreign organizations working on soil water conservation programmes and policy-makers during their early planning stages.
Wydawca
Czasopismo
Rocznik
Tom
Strony
855--872
Opis fizyczny
Bibliogr. 78 poz.
Twórcy
autor
- Rural Revival and Restoration Engineering (RUVIVAL), Institute of Wastewater Management and Water Protection, Hamburg University of Technology, Eißendorfer Straße 42, 21073 Hamburg, Germany
- Department of Chemical Engineering, Mekelle University, Tigray, Ethiopia
autor
- Rural Revival and Restoration Engineering (RUVIVAL), Institute of Wastewater Management and Water Protection, Hamburg University of Technology, Eißendorfer Straße 42, 21073 Hamburg, Germany
autor
- Department of Geography, Adigrat University, Tigray, Ethiopia
Bibliografia
- 1. Abeyou A (2013) “Realistic Assessment of Irrigation Potential on Lake Tana Basin, Addis Ababa Ethiopia.” (December): 9–10
- 2. Adham A, Riksen M, Ouessar M, Ritsema CJ (2016) A methodology to assess and evaluate rainwater harvesting techniques in (semi-) arid regions. Water (Switzerland) 8(5):1–23
- 3. Adham A, Sayl KN, Abed R, Abdeladhim MA, Wesseling JG, Riksen M, Fleskens L, Karim U, Ritsema CJ (2018) A GIS-based approach for identifying potential sites for harvesting rainwater in the Western Desert of Iraq. Int Soil Water Conserv Res 6(4):297–304
- 4. Aghaloo K, Yie-ru C (2020) “Identifying Optimal Sites for a Rainwater-Harvesting Agricultural Scheme in Iran Using the Best-Worst Method and Fuzzy Logic in a GIS-Based Decision”
- 5. Ahmed HR (2012) “GIS Spatial Modeling for Land Degradation Assessment in Tigray , Ethiopia .” 161–66
- 6. Alemu B, Kidane D (2014) The implication of integrated watershed management for rehabilitation of degraded lands: case study of Ethiopian highlands. J Agric Biodivers Res 3(6):78–90
- 7. Alwan IA, Aziz NA, Hamoodi MN (2020) Potential water harvesting sites identification using spatial multi-criteria evaluation in Maysan Province, Iraq. ISPRS Int J Geo-Inf 9(4):235
- 8. Ammar A, Riksen M, Ouessar M, Ritsema C (2016) Identification of suitable sites for rainwater harvesting structures in arid and semi-arid regions: a review. Int Soil Water Conserv Res 4(2):108–120
- 9. Anon. n.d. “Nji and Fonteh, 2002.Pdf”
- 10. Article R (2014). “Properties of Anthropogenic Soils in Ancient Run-off Capturing Agricultural Terraces in the Central Negev Desert ( Israel) and Related Effects of Biochar and Ash on Crop Growth.” 779–92
- 11. Balehegn M, Haile M, Fu C, Liang W (2019) Ecosystem-Based Adaptation in Tigray , Northern Ethiopia : a Systematic Review of Interventions , Impacts, and Challenges
- 12. Behailu M, Haile M (2003) “Water Harvesting in Northern Ethiopia: Environmental, Health and Socio-Economic Impacts.” MoWR/EARO/IWMI/ILRI Workshop 185–191
- 13. Buda AR, Kleinman PJA, Srinivasan MS, Bryant RB, Feyereisen GW (2009) “Factors Influencing Surface Runoff Generation from Two Agricultural Hillslopes in Central Pennsylvania ‡.” 1312 (January):1295–1312
- 14. Chen Z (2015) “Runoff Farming.” Rainwater Harvesting for Agriculture and Water Supply 307–69
- 15. Descheemaeker K, Muys B, Nyssen J, Sauwens W, Haile M, Poesen J, Raes D, Deckers J (2009) Humus form development during forest restoration in exclosures of the Tigray Highlands, Northern Ethiopia. Restor Ecol 17(2):280–289
- 16. de Winnaar G, Jewitt GPW, Horan M (2007) A GIS-based approach for identifying potential runoff harvesting sites in the Thukela River Basin, South Africa. Phys Chem Earth 32(15–18):1058–1067
- 17. Djuma H, Bruggeman A, Camera C, Eliades M (2017) “The Impact of a Check Dam on Groundwater Recharge and Sedimentation in an Ephemeral Stream.” 1–16
- 18. Effat HA, Hassan OA (2013) Designing and evaluation of three alternatives highway routes using the analytical hierarchy process and the least-cost path analysis, application in Sinai Peninsula, Egypt. Egypt J Remote Sens Space Sci 16(2):141–151
- 19. Feizizadeh B, Blaschke T (2013) Land suitability analysis for Tabriz County, Iran: a multi-criteria evaluation approach using GIS. J Environ Plan Manag 56(1):1–23
- 20. Forward W (2020) “A Review of Roof and Pond Rainwater Harvesting Systems for Water Security : The Design , Performance”
- 21. Gebreegziabher T, Nyssen J, Govaerts B, Getnet F, Behailu M, Haile M, Deckers J (2009) Contour Furrows for in situ soil and water conservation, Tigray, Northern Ethiopia. Soil Tillage Res 103(2):257–264
- 22. Grum B, Woldearegay K, Hessel R, Baartman JEM, Abdulkadir M, Yazew E, Kessler A, Ritsema CJ, Geissen V (2017) Assessing the effect of water harvesting techniques on event-based hydrological responses and sediment yield at a catchment scale in Northern Ethiopia using the Limburg soil erosion model (LISEM). CATENA 159(August):20–34
- 23. Haile BM, Natea Merga S (2002) “Workshop on The Experiences of Water Harvesting in the Drylands of Ethiopia: Principles and Practices” (19): 1–111
- 24. Haile G, Suryabhagavan KV (2019) GIS-based approach for identification of potential rainwater harvesting sites in Arsi Zone, Central Ethiopia. Model Earth Syst Environ 5(1):353–367
- 25. Haregeweyn N, Berhe A, Tsunekawa A, Tsubo M, Meshesha DT (2012) Integrated watershed management as an effective approach to curb land degradation: a case study of the enabered watershed in Northern Ethiopia. Environ Manag 50(6):1219–1233
- 26. Hengsdijk H, Meijerink GW, Mosugu ME (2005) Modeling the effect of three soil and water conservation practices in Tigray, Ethiopia. Agr Ecosyst Environ 105(1–2):29–40
- 27. Ibrahim GRF, Rasul A, Ali Hamid A, Fattah Ali Z, Ahmad Dewana A (2019) “Suitable site selection for rainwater harvesting and storage case study using Dohuk Governorate.” Water (Switzerland) 11(4)
- 28. Kahinda J, Mwenge ESB, Lillie AE, Taigbenu MT, Boroto RJ (2008) Developing suitability maps for rainwater harvesting in South Africa. Phys Chem Earth 33(8–13):788–799
- 29. Ketsela GM (2009) “Identification of Potential Rain Water Harvesting Areas. Central Rift Valley of Ethiopia Using a GIS Based Methodology.” 129
- 30. Mahmood K, Qaiser A, Farooq S (2020) RS - and GIS - based modeling for optimum site selection in rain water harvesting system : an SCS - CN approach. Acta Geophys 68(4):1175–1185
- 31. Mahmoud SH, Alazba AA (2015) The potential of in situ rainwater harvesting in Arid regions: developing a methodology to identify suitable areas using GIS-based decision support system. Arab J Geosci 8(7):5167–5179
- 32. Mati B, De Bock T (2006) “Mapping the Potential of Rainwater Harvesting Technologies in Africa.” A GIS Overview, (6)
- 33. Mati B (2020) “BEST PRACTICES FOR RAINWATER HARVESTING FROM OPEN SURFACES Nile Basin Initiative—NELSAP Regional Agricultural Trade and Productivity Project (RATP) Training Manual 2 By : Bancy M . Mati.” (March 2012)
- 34. Merrey DJ, Drechsel P, Pennin FWT, Vries De, Sally H (2005) Integrating ‘Livelihoods’ into integrated water resources management: taking the integration paradigm to its logical next step for developing countries. Reg Environ Change 5(4):197–204
- 35. Miller W, Collins MG, Steiner FR, Cook E (1998) An approach for greenway suitability analysis. Landsc Urban Plan 42(2–4):91–105
- 36. Mugo GM, Odera PA (2019) Site selection for rainwater harvesting structures in Kiambu County-Kenya. Egypt J Remote Sens Space Sci 22(2):155–164
- 37. Mwenge Kahinda J, Taigbenu AE, Sejamoholo BBP, Lillie ESB, Boroto RJ (2009) A GIS-based decision support system for rainwater harvesting (RHADESS). Phys Chem Earth 34(13–16):767–775
- 38. Nyssen J, Mitiku Haile J, Moeyersons JP, Deckers J (2000) Soil and water conservation in Tigray (Northern Ethiopia): the traditional daget technique and its integration with introduced techniques. Land Degrad Dev 11(3):199–208
- 39. Nyssen J, Clymans W, Descheemaeker K, Poesen J, Vandecasteele I, Vanmaercke M, Zenebe A, Van Camp M, Haile M, Haregeweyn N, Moeyersons J, Martens K, Gebreyohannes T, Deckers J, Walraevens K (2010) Impact of soil and water conservation measures on catchment hydrological response-a case in North Ethiopia. Hydrol Process 24(13):1880–1895
- 40. Oweis (1998) “Determination of Potential Sites and Methods for Water Harvesting in Central Syria.” Towards Sustainable Land Use Bonn, Germ(October):Germany, 26-Germany, 30
- 41. Oweis TY, Prinz D, Hachum AY (2012) Rainwater Harvesting for Agriculture in the Dry Areas
- 42. Pradhan MP (2017) “Automatic Asso Ciation of Strahler ’ s Order and Attributes with the Drainage System.” (January 2012)
- 43. Pramanik MK (2016) Site suitability analysis for agricultural land use of Darjeeling District using AHP and GIS techniques. Model Earth Syst Environ 2(2):1–22
- 44. Prinz D (1996) “Water Harvesting—Past and Future.” Sustainability of Irrigated Agriculture 137–68
- 45. Prinz D, Singh A (2000a) “Technological Potential for Improvements of Water Harvesting.” Gutachten Für Die World Commission on Dams, … 1–10
- 46. Prinz D, Singh AK (2000b) “Technological Potential for Improvements of Water Harvesting : Study for the World Commission on Dams, Cape Town, South Africa.” Africa 11
- 47. Rabia AH, Afifi RR, Gelaw AM (2013) Soil mapping and classification: a case study in the Tigray Region, Ethiopia. J Agric 107(1):73–99
- 48. Rabia AH (2012) “A GIS Based Land Suitability Assessment for Agricultural Planning in Kilte Awulaelo District , Ethiopia.” (July 2012):1–10
- 49. Raj A, Jhariya MK, Toppo P, Oraon PR (2017) Role of agroforestry in nutrient cycling. KisanWorld 44(7):38–40
- 50. Rajasekhar M, Raju Gadhiraju S, Kadam A (2020) “Identification of Groundwater Recharge-Based Potential Rainwater Harvesting Sites for Sustainable Development of a Semiarid Region of Southern India Using Geospatial, AHP , and SCS-CN Approach”
- 51. Rana VK, Suryanarayana TMV (2020) GIS-based multi criteria decision making method to identify potential runoff storage zones within watershed. Ann GIS 26(2):149–168
- 52. Robock A, Vinnikov KY, Srinivasan G, Entin JK, Hoiiinger SE, Speranskaya NA, Liu S, Namkhai A (1994) “The Global Soil Moisture Data Bank”
- 53. Rockström J, Falkenmark M (2015) Agriculture: increase water harvesting in Africa. Nature 519(7543):283–285
- 54. Rwanga SS, Ndambuki JM (2017) Accuracy assessment of land use/land cover classification using remote sensing and GIS. Int J Geosci 08(04):611–622
- 55. Saaty T, Pressures S, Resources W, Interests V, Values C (1980) “The Analytic Hierarchy Process (AHP) for Decision Making By Thomas Saaty Decision Making Involves Setting Priorities and the AHP Is the Methodology for Doing Most Decision Problems Are Multicriteria Maximize Profits Satisfy Customer Demands Maximize Emp.” Alternatives 1–69
- 56. Saha A, Patil M, Karwariya S, Pingale SM, Azmi S, Goyal VC, Rathore DS (2018) “Identification of potential sites for water harvesting structures using geospatial techniques and multi-criteria.” XLII(November):20–23
- 57. Segers K, Dessein J, Nyssen J, Haile M, Deckers J (2008) Developers and farmers intertwining interventions: the case of rainwater harvesting and food-for-work in Degua Temben, Tigray, Ethiopia. Int J Agric Sustain 6(3):173–182
- 58. Singh S (2020) “And Soil Properties in Montane Ecosystems Understanding the Role of Slope Aspect in Shaping the Vegetation Attributes and Soil Properties in Montane Ecosystems.” (September 2018)
- 59. Strahler AN (1957) Quantitative analysis of watershed geomorphology. EOS Trans Am Geophys Union 38(6):913–920
- 60. Tabor JA (1995) Improving crop yields in the Sahel by means of water-harvesting. J Arid Environ 30(1):83–106
- 61. Tadesse A, Gebrelibanos G, Gebrehiwot M (2016) Characterization and site suitability analysis of water harvesting technologies: the case of Abreha We Atsbeha watershed, Northern Ethiopia. J Drylands 6(2):531–545
- 62. Tadesse A, Sibehatleab M, Gebrelibanos T, Gebru F, Birhane E (2017) Hydrological response to changes in land use land cover and water harvesting technologies in Abreha Weatsbeha watershed, Northern Ethiopia. J Drylands 7(1):568–581
- 63. Temesgen B (2011) “By : Temesgen Girmay Gebremariam Indra Gandhi National Open University School of Graduate Studies Department of Rural Development A Study on Economic Status of Rural Women in Tigray By: Temesgen Girmay Gebremariam REQUIREMENT FOR DEGREE OF MASTER OF ART”
- 64. Thakkar A, Desai V, Patel A, Potdar M (2015) Land use/land cover classification using remote sensing data and derived indices in a heterogeneous landscape of a Khan-Kali watershed, Gujarat. Asian J Geoinform 14(4):51–13
- 65. Tiwari K, Goyal R, Sarkar A (2018) GIS-based methodology for identification of suitable locations for rainwater harvesting structures. Water Resour Manag 32(5):1811–1825
- 66. Tumbo SD, Mbilinyi BP, Mahoo HF, Mkilamwinyi FO (2013) “Identification of Suitable Indices for Identification of Potential Sites for Rainwater Harvesting.” Tanzania J Agric Sci 12(2)
- 67. Usda S (1986) “Urban Hydrology for Small.” Soil Conservation (Technical Release 55 (TR-55)):164
- 68. Vancampenhout K, Nyssen J, Gebremichael D, Deckers J, Poesen J, Haile M, Moeyersons J (2006) Stone bunds for soil conservation in the Northern Ethiopian Highlands: impacts on soil fertility and crop yield. Soil Tillage Res 90(1–2):1–15
- 69. Vohland K, Barry B (2009) A review of in situ rainwater harvesting (RWH) practices modifying landscape functions in African Drylands. Agr Ecosyst Environ 131(3–4):119–127
- 70. Western A, Walker JP, Costelloe JF (2006) “Controls on Patterns of Soil Moisture in Arid and Semi-Arid Systems Chapter 7 CONTROLS ON PATTERNS OF SOIL MOISTURE IN ARID AND.” (January)
- 71. Woldu G (2019) “Access to Small Scale Irrigation and Farm Households Crop Choice Decision in Kilteawlaelo Woreda of Eastern Tigrai Journal Of Harmonized Research (JOHR) Journal Of Harmonized Research in Management.” (May 2015)
- 72. Woyessa YE, Bennie ATP (2004) Factors affecting runoff and soil loss under simulated rainfall on a Sandy Bainsvlei Amalia Soil. S Afr J Plant Soil 21(4):203–208
- 73. Wu RS, Molina GLL, Hussain F (2018) Optimal sites identification for rainwater harvesting in Northeastern Guatemala by analytical hierarchy process. Water Resour Manag 32(12):4139–4153
- 74. Zahedi A (2019) “Towards Sustainable Development by New Town Planning : Case Study of Mazandaran Province of Iran.” Technische Universität Hamburg
- 75. Zerssa G, Feyssa D, Kim D-G, Eichler-löbermann B (2021) “Challenges of Smallholder Farming in Ethiopia and Opportunities by Adopting Climate-Smart Agriculture.” 1–25
- 76. Zhan X, Huang ML (2004) ArcCN-Runoff: an ArcGIS tool for generating curve number and runoff maps. Environ Model Softw 19(10):875–879
- 77. Zheng H, Gao J, Xie G, Jin Y, Zhang B (2018) Identifying important ecological areas for potential rainwater harvesting in the semi-arid area of Chifeng, China. PloS One 13(8):1–16
- 78. Ziadat F, Bruggeman A, Oweis T, Haddad N, Mazahreh S, Sartawi W, Syuof M (2012) A participatory GIS approach for assessing land suitability for rainwater harvesting in an Arid Rangeland environment. Arid Land Res Manag 26(4):297–311
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-62e14b22-dd80-4173-bbaf-e1e2e02dbc3f