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TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS

Yıl 2018, Cilt: 13 Sayı: 2, 74 - 86, 21.04.2018

Öz

The temperature and dissolved oxygen parameters of Almus Dam Lake located in the district Almus of province Tokat were seasonally determined at nine stations located along the lake. The water quality class of Almus Dam Lake was determined by comparing the results of our measured parameters with the values of Intercontinental Water Sources Quality Classification. The spatial and seasonal variations in physical parameters were analyzed with the Two-Way ANOVA, the relationships among these parameters. According to Intercontinental Water Sources Quality Classification, Almus Dam Lake has Class I water quality when considering parameters of temperature (14.30±7.44C°), dissolved oxygen (10.15±2.67mg/L. With the examination of seasonal temperature-depth profile, it was observed that winter stagnation and spring and fall vertical mixing occurred during the January and March and spring May and November, respectively. Temperature stratification was clearly observed during the July and September. Epilimnion, metalimnion (thermocline) and hypolimnion were well clearly visible at the first 10 meters, between 10– 20 meters, and below 20 meters, respectively. GIS maps with spatial and seasonal values were created for temperature and dissolved oxygen variables.



Kaynakça

  • [1] Kennedy, R.H., (1999). Reservoir Design and Operation: Limnological Implications and Management Opportunities. In: Tundisi, J.G., Straskraba, M. (Eds.), Theoretical reservoir ecology and its applications, Backhuys, Leiden, pp:1-28.
  • [2] Bayhan, H., Erguven, G.O., Akkoyunlu, A., and Kanat, G., (2017). The assessment of water quality in Omerli Dam Reservoir, Istanbul, Turkey, Fresenius Environmental Bulletin, Volume:26-1a, pp:977-978.
  • [3] EPA841-B-98-007, (1998). Lake and Reservoir Bioassessment and Biocriteria Technical Guidance Document, Office of Water, Washington, DC (4504F).
  • [4] Soltani, j. and Alavi Moghadam, M.R., (2005). The Effect of Thermal Stratification on Water Quality in Iran's Dams-An Overview, Proceedings of 8th National Conference of Environmental Health, Tehran, Iran, Volume:1, Number:1, pp:8-10.
  • [5] Shoo, G.B., Schladow, S.G., Reuter, J.E., and Coats, R., (2011). Effects of Climate Change on Thermal Properties of Lakes and Reservoirs, and Possible Implications. Stoch. Environ. Res. Risk Asses., Volume:25, pp:445–456.
  • [6] Snortheima, C.A., Hanson, P.C, McMahon, K.D., Read, J.S., Careyc, C.C., and Dugan, H.A., (2017). Meteorological Drivers of Hypolimnetic Anoxia in Eutrophic, Northtemperate Lake. Ecological Modelling, Volume:343, pp:39–53.
  • [7] Polat, F., (2009). Evaluation of some Physicochemical Paremeters of Almus Dam Lake with Geographic Information Systems and modeling its phosphorous carrying capacity, Doctorate Thesis, Firat University Graduate School of Natural and Applied Sciences Department of Chemistry, pp:1-139.
  • [8] Cirik, Ş., (1991). Limnology Course Book, Ege University Water Products High School Publications No:21, Bornova, İzmir. [9] Wetzel, R.G., (1975). Limnology, Saunders.
  • [10] Mazumder, A. and Taylor, W.D., (1994). Thermal Structure of Lakes Varying in Size and Water Clarity, Limnol. Oceanogr, Volume:39, pp:968-976.
  • [11] Yu, N. and Culver, D.A., (2000). Can Zebra Mussels Change Stratification patterns in a small reservoir?. Hydrobiologia, Volume:431, pp:175-184.
  • [12] Talling, J.F., (2003). Some Observations on the Stratification of Lake Victoria, Limnology and Oceanography, Volume:2, Number:3, pp:1-9.
  • [13] Mazumder, A., (1990). Ripple Effects: How Lake Dwellers Control The temperature and clarity Of their habitat, The Sciences, Volume:30, Number:6, pp:38-42.
  • [14] Mazumder, A., Taylor, W.D., Mc, Queen, D.j., Lean, D.R.S., (1990). Effects of Fish and Plankton on Lake Temperature and Mixing Depth. The Sicience, Volume:247, pp:312-315.
  • [15] Nahimana, D., Brion, N., Baeyens, W., and Ntakimazi, G., (2008). General Nutrient Distribution in Water Column of Northern Lake Tanganyika, Aquatic Ecosystem Health and Management Society, Volume:11, Number:1, pp:8-15.
  • [16] Cocker, M.D. and Shapiro, E.A., (1999). The Continental margins Program in Georgia, Marine Georesources and Geotechnology, Volume:17, pp:199-209.
  • [17] Wang, F., Han, L., Kung, H.T., and Arsdale, B.V., (2006). Applications of Landsat-5 TM imageny in assessing and mapping water quality in Reelfoot Lake, Tennessee”, International Journal of Remote Sensing, pp:27-23.
  • [18] Dwiwedi, R.M. and Narin, A., (1987). Remote Sensing of Phytoplankton, an Attempt from the Landsat Thematic Mapper, International Journal of Remote Sensing, Volume:8, pp:1563-1569.
  • [19] Lathrop, R.G., (1992). Landsat Thematic Mapper Monitoring of Turbid Inland Water Quality, Photogrammetric Engineering and Remote Sensing, Volume:58, pp:465-470.
  • [20] Tran, K.C., Valdes, D., Euan, J., Real, E., and Gil, E., (2002). Status of Water Quality at Holbox Island, Quintana Roo State, Mexico, Aquatic Ecosystem Health & Management, Volume:5, Number:2, pp:173-189.

YEŞİLIRMAK NEHRİ (TÜRKİYE) ÜZERİNDE BULUNAN ALMUS BARAJ GÖLÜ’NDE SICAKLIK VE ÇÖZÜNMÜŞ OKSİJEN TABAKALAŞMASI VE CBS HARİTALARI

Yıl 2018, Cilt: 13 Sayı: 2, 74 - 86, 21.04.2018

Öz

Yeşilırmak Nehri üzerinde bulunan Almus Baraj Gölü’nde belirlenen 9 istasyonda sıcaklık ve çözünmüş oksijen parametreleri mevsimsel ve alansal olarak tespit edilmiştir. Çalışmada fiziksel parametrelere ait bulgular “Kıta İçi Su kaynakları Kalite Sınıflandırılması” değerleri ile karşılaştırılarak, Almus Baraj Gölü’nün ölçülen parametreler (sıcaklık ve çözünmüş oksijen) açısından su kalite sınıfları tespit edilmiştir. İlgili parametrelerde meydana gelen mevsimsel ve alansal değişimleri tespit etmek için; iki yönlü varyans analizi (ANOVA) testi kullanılmıştır. Kıta İçi Su kaynakları Kalite Sınıflandırılmasına göre Almus Baraj Gölü sıcaklık (14.30±7.44C°), çözünmüş oksijen (10.15±2.67mg/L) açısından I. sınıf su kalitesine sahiptir. Sıcaklık değerlerinin derinliğe göre değişimi incelendiğinde, Almus Baraj Gölü’nde Ocak ve Mart aylarında kış stangasyonu, Mayıs ve Kasım aylarında ilkbahar ve sonbahar karışımı, Temmuz ve Eylül aylarında ilk 10m’de epilimnion, 10 ile 20m arasında termoklin, 20m’den aşağı derinliklerde ise hipolimnion tabakası tespit edilmiştir. Sıcaklık ve çözünmüş oksijen değişkenleri için mekânsal ve mevsimsel değerlere sahip CBS haritaları oluşturulmuştur.



Kaynakça

  • [1] Kennedy, R.H., (1999). Reservoir Design and Operation: Limnological Implications and Management Opportunities. In: Tundisi, J.G., Straskraba, M. (Eds.), Theoretical reservoir ecology and its applications, Backhuys, Leiden, pp:1-28.
  • [2] Bayhan, H., Erguven, G.O., Akkoyunlu, A., and Kanat, G., (2017). The assessment of water quality in Omerli Dam Reservoir, Istanbul, Turkey, Fresenius Environmental Bulletin, Volume:26-1a, pp:977-978.
  • [3] EPA841-B-98-007, (1998). Lake and Reservoir Bioassessment and Biocriteria Technical Guidance Document, Office of Water, Washington, DC (4504F).
  • [4] Soltani, j. and Alavi Moghadam, M.R., (2005). The Effect of Thermal Stratification on Water Quality in Iran's Dams-An Overview, Proceedings of 8th National Conference of Environmental Health, Tehran, Iran, Volume:1, Number:1, pp:8-10.
  • [5] Shoo, G.B., Schladow, S.G., Reuter, J.E., and Coats, R., (2011). Effects of Climate Change on Thermal Properties of Lakes and Reservoirs, and Possible Implications. Stoch. Environ. Res. Risk Asses., Volume:25, pp:445–456.
  • [6] Snortheima, C.A., Hanson, P.C, McMahon, K.D., Read, J.S., Careyc, C.C., and Dugan, H.A., (2017). Meteorological Drivers of Hypolimnetic Anoxia in Eutrophic, Northtemperate Lake. Ecological Modelling, Volume:343, pp:39–53.
  • [7] Polat, F., (2009). Evaluation of some Physicochemical Paremeters of Almus Dam Lake with Geographic Information Systems and modeling its phosphorous carrying capacity, Doctorate Thesis, Firat University Graduate School of Natural and Applied Sciences Department of Chemistry, pp:1-139.
  • [8] Cirik, Ş., (1991). Limnology Course Book, Ege University Water Products High School Publications No:21, Bornova, İzmir. [9] Wetzel, R.G., (1975). Limnology, Saunders.
  • [10] Mazumder, A. and Taylor, W.D., (1994). Thermal Structure of Lakes Varying in Size and Water Clarity, Limnol. Oceanogr, Volume:39, pp:968-976.
  • [11] Yu, N. and Culver, D.A., (2000). Can Zebra Mussels Change Stratification patterns in a small reservoir?. Hydrobiologia, Volume:431, pp:175-184.
  • [12] Talling, J.F., (2003). Some Observations on the Stratification of Lake Victoria, Limnology and Oceanography, Volume:2, Number:3, pp:1-9.
  • [13] Mazumder, A., (1990). Ripple Effects: How Lake Dwellers Control The temperature and clarity Of their habitat, The Sciences, Volume:30, Number:6, pp:38-42.
  • [14] Mazumder, A., Taylor, W.D., Mc, Queen, D.j., Lean, D.R.S., (1990). Effects of Fish and Plankton on Lake Temperature and Mixing Depth. The Sicience, Volume:247, pp:312-315.
  • [15] Nahimana, D., Brion, N., Baeyens, W., and Ntakimazi, G., (2008). General Nutrient Distribution in Water Column of Northern Lake Tanganyika, Aquatic Ecosystem Health and Management Society, Volume:11, Number:1, pp:8-15.
  • [16] Cocker, M.D. and Shapiro, E.A., (1999). The Continental margins Program in Georgia, Marine Georesources and Geotechnology, Volume:17, pp:199-209.
  • [17] Wang, F., Han, L., Kung, H.T., and Arsdale, B.V., (2006). Applications of Landsat-5 TM imageny in assessing and mapping water quality in Reelfoot Lake, Tennessee”, International Journal of Remote Sensing, pp:27-23.
  • [18] Dwiwedi, R.M. and Narin, A., (1987). Remote Sensing of Phytoplankton, an Attempt from the Landsat Thematic Mapper, International Journal of Remote Sensing, Volume:8, pp:1563-1569.
  • [19] Lathrop, R.G., (1992). Landsat Thematic Mapper Monitoring of Turbid Inland Water Quality, Photogrammetric Engineering and Remote Sensing, Volume:58, pp:465-470.
  • [20] Tran, K.C., Valdes, D., Euan, J., Real, E., and Gil, E., (2002). Status of Water Quality at Holbox Island, Quintana Roo State, Mexico, Aquatic Ecosystem Health & Management, Volume:5, Number:2, pp:173-189.
Toplam 19 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Bölüm Makaleler
Yazarlar

Fatih Polat

Tarık Dal Bu kişi benim

İlhami Karataş

Ekrem Buhan Bu kişi benim

Yayımlanma Tarihi 21 Nisan 2018
Yayımlandığı Sayı Yıl 2018 Cilt: 13 Sayı: 2

Kaynak Göster

APA Polat, F., Dal, T., Karataş, İ., Buhan, E. (2018). TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS. Ecological Life Sciences, 13(2), 74-86.
AMA Polat F, Dal T, Karataş İ, Buhan E. TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS. NWSA. Nisan 2018;13(2):74-86.
Chicago Polat, Fatih, Tarık Dal, İlhami Karataş, ve Ekrem Buhan. “TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS”. Ecological Life Sciences 13, sy. 2 (Nisan 2018): 74-86.
EndNote Polat F, Dal T, Karataş İ, Buhan E (01 Nisan 2018) TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS. Ecological Life Sciences 13 2 74–86.
IEEE F. Polat, T. Dal, İ. Karataş, ve E. Buhan, “TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS”, NWSA, c. 13, sy. 2, ss. 74–86, 2018.
ISNAD Polat, Fatih vd. “TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS”. Ecological Life Sciences 13/2 (Nisan 2018), 74-86.
JAMA Polat F, Dal T, Karataş İ, Buhan E. TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS. NWSA. 2018;13:74–86.
MLA Polat, Fatih vd. “TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS”. Ecological Life Sciences, c. 13, sy. 2, 2018, ss. 74-86.
Vancouver Polat F, Dal T, Karataş İ, Buhan E. TEMPERATURE AND DISSOLVED OXYGEN STRATIFICATION IN ALMUS DAM LAKE ON YEŞILIRMAK RIVER (TURKEY) AND ITS GIS MAPS. NWSA. 2018;13(2):74-86.