Determination and assessment of phosphorus assimilation capacity applying Vollenweider approach for Hazar Lake
Year 2021,
, 72 - 81, 30.04.2021
Selma Ayaz
,
Mehmet Dilaver
Abstract
Eutrophication is a natural process for natural lakes and dams and the hydraulic retention time of this process is directly related to whether the assimilation capacity is exceeded depending on the current water quality and pressures consists of point and diffuse sources. Exceeding assimilation capacity is accepted good for biological productivity however this situation cannot be desired for water resources any time and preventive actions need to be taken to sustain good water quality. The Vollenweider OECD Method is a widely used and accepted approach in order to calculate current phosphorus loads for phosphorus limiting lakes and dams. In addition to OECD method, rational method is used frequently in calculating the flowrates via surface run-off after precipitation. In this study, the calculation of the assimilation capacity for phosphorus limiting lakes and dams using the Vollenweider Method and rational method for calculation of flowrates were applied for Hazar Lake’s Basin example. When the apply proposed approach Hazar Lake’s TP loading might be increased 3.7 times a year for desired oligotrophic upper boundary condition and 13.7 times a year for mesotrophic state boundary condition.
Supporting Institution
TC Orman ve Su İşleri Bakanlığı
Thanks
This study was prepared within the scope of the project “Determination of Sensitive Areas and Water Quality Objectives for Turkish River Basin Districts” (2012–2015) conducted by the former Ministry of Forestry and Water Affairs/Directorate General for Water Management in collaboration with TUBITAK MRC Environment and Cleaner Production Institute. The authors thank the General Directorate of Water Management for financial support. The lake monitoring studies were carried out by Fırat University (Prof. Dr. Bülent Şen, Prof. Dr. Feray Sönmez and their team). The authors also thank TUBITAK MRC Environment and Cleaner Production Institute's laboratory staff and GIS team for their valuable support.
References
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Year 2021,
, 72 - 81, 30.04.2021
Selma Ayaz
,
Mehmet Dilaver
References
- [1] R.A. Vollenweider, Advances in defining critical loading levels for phosphorus in lake eutrophication, Mem. 1st ital. Idrobiol. 33 (1976) 53–58.
- [2] L. Håkanson, A.C. Bryhn, J.K. Hytteborn, On the issue of limiting nutrient and predictions of cyanobacteria in aquatic systems, Sci. Total Environ. 379 (2007) 89–108.
- [3] P. Ekholm, N: P ratios in estimating nutrient limitation in aquatic systems, Finnish Environ. Inst. (2008) 11–14.
- [4] R.W. Sterner, On the phosphorus limitation paradigm for lakes, Int. Rev. Hydrobiol. 93 (2008) 433–445.
- [5] R.A. Jones, G.F. Lee, Use of Vollenweider-OECD modeling to evaluate aquatic ecosystem functioning, içinde: Funct. Test. Aquat. Biota Estim. Hazards Chem., ASTM International, 1988.
- [6] S.-O. Ryding, C. Forsberg, Short-term load-response relationships in shallow, polluted lakes, içinde: Hypertrophic Ecosyst., Springer, 1980: ss. 95–103.
- [7] J.R. Jones, R.W. Bachmann, Prediction of phosphorus and chlorophyll levels in lakes, J. (Water Pollut. Control Fed. (1976) 2176–2182.
- [8] D.W. Schindler, Factors regulating phytoplankton production and standing crop in the world’s freshwaters, Limnol. Oceanogr. 23 (1978) 478–486.
- [9] S.C. Chapra, Total phosphorus model for the Great Lakes, J. Environ. Eng. Div. 103 (1977) 147–161.
- [10] D.E. Canfield Jr, R.W. Bachmann, Prediction of total phosphorus concentrations, chlorophyll a, and Secchi depths in natural and artificial lakes, Can. J. Fish. Aquat. Sci. 38 (1981) 414–423.
- [11] F. Sonmez, M.A.T. Kocer, M.T. Alp, B. Sen, AN EVALUATION ON CHARACTERISTIC DIATOMS OF ALKALINE LAKE HAZAR (TURKEY), FEB-FRESENIUS Environ. Bull. (2018) 8519.
- [12] L. Håkanson, M. Jansson, Principles of lake sedimentology, Springer-verlag Berlin, 1983.
- [13] E. Emmanuel, G. Keck, J.-M. Blanchard, P. Vermande, Y. Perrodin, Toxicological effects of disinfections using sodium hypochlorite on aquatic organisms and its contribution to AOX formation in hospital wastewater, (2004). doi:10.1016/j.envint.2004.02.004.
- [14] G.K. Nürnberg, Trophic state of clear and colored, soft-and hardwater lakes with special consideration of nutrients, anoxia, phytoplankton and fish, Lake Reserv. Manag. 12 (1996) 432–447.
- [15] M. Varol, STREAM INPUTS TO LAKE HAZAR (EASTERN ANATOLIA-TURKEY)., Environ. Eng. Manag. J. 18 (2019).
- [16] M.A.T. Kocer, B. ŞEN, The seasonal succession of diatoms in phytoplankton of a soda lake (Lake Hazar, Turkey), Turk. J. Botany. 36 (2012) 738–746.
- [17] M.A.T. Kocer, B. ŞEN, Some factors affecting the abundance of phytoplankton in an unproductive alkaline lake (Lake Hazar, Turkey), Turk. J. Botany. 38 (2014) 790–799.
- [18] R.B. Baird, Standard Methods for the Examination of Water and Wastewater, 23rd, Water Environment Federation, American Public Health Association, American …, 2017.
- [19] RSWQ, Regulation on Surface Water Quality (RSWQ) (Turkey) (2016) 29797/ 16.8.2016. Ministry of Forestry and Water Affairs (in Turkish).
- [20] G. Phillips, O.-P. Pietiläinen, L. Carvalho, A. Solimini, A.L. Solheim, A.C. Cardoso, Chlorophyll–nutrient relationships of different lake types using a large European dataset, Aquat. Ecol. 42 (2008) 213–226.
- [21] B. Şen, M.T. Alp, F. Özrenk, Y. Ercan, V. Yıldırım, A study on the amount of plant nutrients and organic matters carried into the Hazar Lake (Elazığ-Türkiye), Fresenius Environ. Bull. 8 (1999) 272–279.
- [22] Ayaz S., Hazar Lake Management Plan Project I. Stage, TÜBİTAK MRC, Energy Systems and Cleaner Production Institute.
- [23] TÜBİTAK MRC, 2016-HHAP Project Determination of Sensitive Areas and Water Quality Objectives for Turkish River Basin Districts” (2012–2015)
- [24] https://www.resmigazete.gov.tr/eskiler/2016/08/20160810-9.htm. Accessed 25th February 2021.
- [25] TURKSTAT, 2020, Turkish Statistical Institute Report.