Evaluation of Eutrophication Levels in Al-Najaf Al-Ashraf Lake, Iraq (Biological and Chemical study)

Al-Sharifi, Suhair R.; Al-Bakri, Salih A.; Al-Bayati, Sataa A.F.

doi:10.30684/etj.v38i10A.1601

	Evaluation of Eutrophication Levels in Al-Najaf Al-Ashraf Lake, Iraq (Biological and Chemical study)
Engineering and Technology Journal
Article 13, Volume 38, 10A, 2020, Pages 1531-1538 PDF (1.39 M)
Document Type: Research Paper
DOI: 10.30684/etj.v38i10A.1601
Authors
Suhair R. Al-Sharifi^* ¹; Salih A. Al-Bakri²; Sataa A.F. Al-Bayati³
¹Civil Engineering Department, University of Kufa, Al-Najaf, Iraq
²Environmental Research Center, University of Technology - Iraq
³Civil Engineering Department, University of Technology - Iraq
Abstract
Within Al-Najaf lake, that is one of the important shallow lakes in Iraq, the lake facing tremendous pressure due to encroachments, discharge of untreated domestic and industrial waste, drainage water from cultivated orchards, dumping of solid waste and illegal diversion of water and currently it's still suffering from these problems and neglect. The study aimed to evaluate the eutrophication status. Eutrophication is a grave problem in lakes, a knowledge about the eutrophic state help in providing a make efficient realization of the eutrophic problem. This study conducted to assess the Eutrophication level with a scale 0 – 100 depending on the trophic state index (TSI) and (CTSI) calculation by measuring (Chl-a), (TP), (TN) and (TSS), also measured the parameters (Tw), (Pb), (TDS), (pH), (EC), (MPN) and (COD). The least significant difference (LSD) and ANOVA analysis were performed by using the Genstat statistical program. Lake can be classified according to the Carlson index as eutrophic (CTSI > 80) most hegemony of blue-green algae, extensive macrophyte troubles. Adding, according to Trophic State Index classification (TSItotal was ranged between 88.104-89.49 depending on TP, TSS, TN, P/N and Chl-a concentrations), were classified as the lake as extremely hypereutrophic and algal scums.
Keywords
Eutrophication; Carlson trophic state index (CTSI); trophic state index (TSI); Total nitrogen (TN); Total phosphorus (TP); Geographical information system (GIS)

References
[1] F. L. Xu, S.Tao, R. W. Dawson and B. G. Li, “A GIS-based method of lake eutrophication assessment,” Ecological modelling, 144, pp. 231-244, 2001. [2] F. Esfandi, A. Mahvi, M. Mosaferi, F. Armanfar, M. Hejazi, and S. Maleki, “Assessment of temporal and spatial eutrophication index in a water dam reservoir,” Global J. Environ. Sci. Manage, 4(2), pp. 153-166, 2018. [3] T. J. Benni, and B. S. Al-Tawash, “Palynological Evidences on Paleoclimate and Paleoenvironmental Changes During Late Quaternary of Bahr Al-Najaf Depression, Central Iraq,” Iraqi Bulletin of Geology and Mining, 7(2), pp.1-28, 2011. [4] APHA, American Public Health Association, “Standard Methods for the Examination of Water and Wastewater,” 21sted Edition Washington, DC., pp. 874, 2005. [5] R. E. Carlson, and J. Simpson, “A Coordinator’s Guide to Volunteer Lake Monitoring Methods,” North American Lake Management Society, 96, pp. 305, 2, 1996. [6] R. E. Carlson, “A trophic state index for lakes,” Limnology and Oceanography, 22, 2, pp. 361-369, 1977. [7] M. Aizaki, T. Iwakuma, and N. Takamura, “Application of modified Carlson’s trophic state index to Japanese lakes and its relationship to other parameters related to trophic state,” Researech Report National. Institute Environmental Studies japan, 23, pp.13-31, 1981. [8] S. Huo, C. Ma, B. Xi, J. Su, F. Zan, D. Ji, and Z. He, “Establishing eutrophication assessment standards for four lake regions, China,” J. Environ. Sci., (China). 25, 10, pp. 2014-2022, 2013. [9] V. Karadzic, G. Subakov-Simic, J. Krizmanic, and D. Natic, “Phytoplankton and eutrophication development in the water supply reservoirs Garasi and Bukulja (Serbia),” Desalination, 255, 1, pp. 91-96, 2010. [10] G. M. Sechi, and A. Sulis, “Dynamic attribution of water quality indexes in a multi-reservoir optimization model,” Desalination, 237, pp. 99–107, 2009. [11] D. D. Kane, J. D. Conroy, R. Peter Richards, D. B. Baker, and D. A. Culver, “Re-eutrophication of Lake Erie: Correlations between tributary nutrient loads and phytoplankton biomass,” Journal of Great Lakes Research, 40, 3, 496-501, 2014. [12] C. A. Stow, J. Dyble, D. R. Kashian, T. H. Johengen, P. W. Kimberly, S. D. Peacor, S. N. Francoeur, A. W. Burtner, D. Palladino, N. Morehead, D. Gossiaux, Y. Y. Cha, S. Q. Song, and D. Miller, “Phosphorus targets and eutrophication objectives in Saginaw Bay: A 35year assessment,” Journal of Great Lakes Research, 40, Supplement 1, 2014. [13] E. Bergman, “Changes In the Nutrient Load and Lake Water Chemistry in Lake Ringsjoin, Southern Sweden From 1966-1996,” Hydrobiologia, 404, pp. 9-18, 1999. [14] M. Kangur, L. Puusepp, O. Buhvestova, M. Haldna, and K. Kangur, “Spatio-temporal Variability of Surface Sediment Phosphorus Fractions and Water Phosphorus Concentration in Lake Peipsi (Estonia/Russia),” Estonian Journal of Earth Sciences, 62, 3, pp. 171-180, 2013. [15] M. Sondergaard, J. P. Jensen, and E. Jeppesen, “Seasonal response of nutrients to reduced phosphorus loading in Danish lakes,” Freshwater Biology, 50, pp. 1605-1615, 2005. [16] R. Gołdyn, T. Joniak, K. Kowalczewska-Madura, and A. Kozak, “Trophic state of a lowland reservoir during 10 years after restoration,” Hydrobiologia, 506–509, pp. 759–765, 2003. [17] X. Ping, “Biological Mechanisms Driving the Seasonal Changes in the Internal Loading of Phosphorus in
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