Water Quality Assessment for Irrigation Water Use in Lake Hazar Basin, Elazığ, Turkey

Yıl 2020, Cilt: 7 Sayı: 1, 231 - 247, 25.01.2020

Murat Çeliker Nurettin Parlakyıldız Mualla Öztürk

https://doi.org/10.30910/turkjans.680077

Öz

The goal of this work was to research the suitability of water sources for agricultural use in the Lake Hazar Basin For this purpose, samples are taken from 61 locations during the wet period and 60 locations during the dry period in 2015 and analyzed pH, electrical conductivity, calcium, magnesium, sodium, potassium, bicarbonate, chloride and sulfate parameters. Based on these analyses sodium percentage (Na%), sodium absorption ratio (SAR), residual sodium carbonate (RSC), magnesium ratio (MR), permeability index (PI) and Kelly’s ratio (KR) were calculated. Also, the usability of groundwater in agricultural activities is evaluated according to Wilcox and United States Salinity Laboratory (USSL) Diagrams. The EC, SAR, Na%, RSC, PI, KR and MR values revealed that suitability of waters as irrigation water, except for a few locations close to the lake. Similar results were obtained from classifications made according to USLL and Wilcox diagrams. The thematic maps of water quality parameters displayed that the groundwater quality decreases along the flow path from high elevations to lake level.

Anahtar Kelimeler

Lake Hazar Basin, irrigation water quality, thematic maps, SAR, Na%

Teşekkür

This work was supported by the Research Fund of Fırat University. Project number: MF. 15.07. The researchers are thankful to the editor and reviewers for their helpful and constructive comments on an earlier draft of this paper.

Hazar Gölü Havzasında (Elazığ, Türkiye) Sulama Suyu Kullanımı için Su Kalite Değerlendirmesi

Öz

Bu çalışmanın amacı Hazar Gölü Havzasında su kaynaklarının tarımsal kullanıma uygunluğunu araştırmaktır. Bu amaçla, 2015 yılının yağışlı döneminde 61 lokasyondan ve kurak döneminde 60 lokasyondan su numuneleri alınmış ve pH, elektriksel iletkenlik, kalsiyum, magnezyum, sodyum, potasyum, bikarbonat, klorür ve sülfat parametreleri analiz edilmiştir. Bu analizlere dayanarak, yüzde sodyum (%Na), sodyum absorbsiyon oranı (SAR), artık sodyum karbonat (RSC), magnezyum oranı (MR), permeabilite indeksi (PI) ve Kelly Oranı (KR) hesaplanmıştır. Ayrıca, yeraltı suyunun tarımsal faaliyetlerde kullanılabilirliği Wilcox ve ABD Tuzluluk Laboratuvarı (USSL) Diyagramlarına göre değerlendirilmiştir. EC, SAR, %Na, RSC, PI, KR ve MR değerleri, göle yakın birkaç yer dışında, suyun sulama suyu olarak uygun olduğunu ortaya koymuştur. ABD Tuzluluk Diyagramı (USLL) ve Wilcox diyagramlarında yapılan sınıflandırmalarda da benzer sonuçlar elde edilmiştir. Tematik su kalitesi parametre haritaları, yeraltı suyu kalitesinin yüksek kotlardan göl seviyesine olan akış yolu boyunca düştüğünü göstermiştir.

Anahtar Kelimeler

Hazar Gölü Havzası, sulama suyu kalitesi, tematik haritalar, SAR, %Na

Kaynakça

• Aksever, F., Davraz, A., Bal, Y. 2016. Assessment of water quality for drinking and irrigation purposes: a case study of Başköy springs (Ağlasun/Burdur/Turkey). Arab J. Geosci, 9: 748.
• Alavi, N., Zaree, E, Hassani, M., Babaei, A.A., Goudarzi, G., Yari, A.R. 2016. Water quality assessment and zoning analysis of Dez eastern aquifer by Schuler and Wilcox diagrams and GIS. Desalination and Water Treatment, 57 (56).
• Ayers, R.S., Westcott, D.W. 1985. Water quality for agriculture (No. 29): Food and Agriculture Organization of the United Nations, Rome, Italy.
• Bozdağ, A., Göçmez, G. 2013.Evaluation of groundwater quality in the Cihanbeyli basin, Konya, Central Anatolia, Turkey, Environmental Earth Sciences. 69: 921–937.
• Çeliker, M. 2008. Hydrogeologic Assessment of Uluova (Elaziğ) By Geographical Information Systems, Çukurova University, Msc Thesis. pp: 103
• Demer, S., Hepdeniz, K. 2018. Assessment of irrigation water quality in Isparta Plain (SW‐ Turkey) using statistic and Geographic Information Systems, Turkish Geographical Review, 70:109‐122.
• DMI. 2016. Elazığ Regional Directorate Station Report (in Turkish), General Directorate of State Meteorological Service, Ankara.
• Doneen, L.D. 1964. Notes on water quality in Agriculture. Published as a Wter Science and Engineering. Paper 4001, Department of Water Sciences and Engineering, University of California.
• Eaton, F.M. 1950. Significance of carbonates in irrigation waters. Soil Science, 69:123-133.
• Jalali, M. 2007. Salinization of groundwater in arid and semi-arid zones: an example from Tajarak, western Iran. Environ. Geol., 52:1133–1149.
• Kelly, W.P. 1940. Permissible composition and concentration of irrigated waters. Proceeding of ASCF 66, 607.
• Khodapanah, L., Sulaiman, W.N.A., Khodapanah, N. 2009. Groundwater quality assessment for different purposes in Eshtehard district, Tehran, Iran. European J. Sci. Research, 36(4): 543-553.
• Karanth K.R. 1987. Groundwater assessment, development and management, Tata-McGraw Hill Publishing Company Limited, New Delhi.
• Kumar S.K., Rammohan V., Sahayam, J., Jeevanandam, M. 2009. Assessment of groundwater quality and hydrogeochemistry of Manimuktha River basin, Tamil Nadu, India. Environmental Monitoring and Assessment, 159, 341–351.
• Oladeji, O.S., Adewoye, A.O., Adegbola, A.A. 2012. Suitability assessment of groundwater resources for irrigation around Otte Village, Kwara State, Nigeria, Int. Journal of Applied Sciences and Engineering Research, 1(3): 437-445.
• Ragunath, H.M. 1987. Groundwater, 2nd edn. Wiley Eastern Ltd, New Delhi.
• Ravikumar, P., Somashekar, R., Angami, M. 2011. Hydrochemistry and evaluation of groundwater suitability for irrigation and drinking purposes in the Markandeya River basin, Belgaum District, Karnataka State, India. Environ. Monit. Assess, 173(1):459–487.
• Richards, L.A., 1954. Diagnosis Improvement Saline Alkali Soils. US Department of Agriculture Handbook. 60.
• Sadashivaiah, C., Ramakrishnaiah, C.R., Ranganna, G. 2008. Hydrochemical Analysis and Evaluation of Groundwater Quality in Tumkur Taluk, Karnataka State, India. Int. J. Environ. Res. Public Health, 5 (3):158-164.
• Saleh, A.F., Al-Ruwaih, M., Shehata, 1999. Hydrogeochemical processes operating within the main aquifers of Kuwait. J. Arid. Envir., 42: 195-209.
• Satyanarayanan, M., Balaram, V., Al Hussin, M.S., Al Jemaili, M.A.R., Rao, T.G., Mathur, R., Dasaram, B., Ramesh, S.L. 2007. Assessment of Groundwater Quality in a Structurally Deformed Granitic Terrain in Hyderabad, India. Environmental Monitoring and Assessment, 131: 117-127.
• Szabolcs, I., Darab C. 1964. The influence of irrigation water of high sodium carbonate content on soils. In I. Szabolics (Ed.), Proc 8th International Congress Soil Science Sodics Soils, Res. Inst. Soil Sci. Agric. Chem. Hungarian Acad. Sci., ISSS Trans II, 1964, 802–812.
• Tiwari, T.N., Manzoor, A. 1988. Pollution of Subarnarekha River near Jamshedpur and the suitability of its water for irrigation. Indian journal of environmental protection, 8(7): 494–497.
• Todd, D.K., 1959. Groundwater Hydrology, International Edition, John Wiley & Sons, Inc., New York.
• Todd, D.K., 1980. Groundwater hydrology (2nd ed.). New York, NY: Wiley.
• USSL, 1954. (United States Salinity Laboratory), Diagnosis and Improvements of Saline and Alkali Soils, US Department of Agricultural Soils, US Department of Agricultural Hand Book 60, Washington, 11.
• Quist, L.G., Bannerman, R.R., Owusu, S. 1988. Groundwater in rural water supply in Ghana In: Ground Water in Rural Water Supply, Report of the West African Sub-Regional Workshop held in Accra, Ghana, 20–24 October, UNESCO Technical Documents in Hydrology, Paris, pp 101–126.
• Wilcox, L.V. 1955. Classification and Use of Irrigation Waters, USDA, Circular 969, Washington DC.