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Risk of heavy metals and their compounds pollution in Port Gdynia waters

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Warianty tytułu
Konferencja
15th Summer Safety & Reliability Seminars - SSARS 2021, 5-12 September 2021, Ciechocinek, Poland
Języki publikacji
EN
Abstrakty
EN
The Baltic Sea is one of the world’s largest brackish water areas and an ecologically unique ecosystem.The Port of Gdynia is a universal modern port specializing in handling of general cargo, mainly unitized cargo transported in containers and in a ro-ro system. Ships traffic in the Port of Gdynia has increased in recent years. Many of ships carry cargo that could severally impact coastal ecosystems if accidentally released. The sea water is influenced by heavy metals and their compounds that originate from both natural and anthropogenic origins. This paper discusses the concentration of heavy metals and their compounds in the Gdynia Port waters. It is based on data collected during the period from 2000 to 2019. The samples were tested and analyzed to find concentration of cadmium, lead and zinc. The level of contamination is lower than the Polish standards. Samples taken from the port area water are non-polluted, and the analysis shows that all metals are within the limits.
Twórcy
  • Gdynia Maritime University, Gdynia, Poland
  • Gdynia Maritime University, Gdynia, Poland
  • Maritime Institute, Gdynia Maritime University, Gdynia, Poland
Bibliografia
  • Almeida, D. F., Martins, A. H. & Tundisi, J.G. 2011. Weight-of-evidence on environmental impact of metal contaminated sediments in the Sao Francisco river (Três Marias - Minas Gerais - Brazil): a case study. Brazilian Journal of Biology 71 (4), 961-971.
  • Bastami, K.D., Neyestani, M.R. Shemirani, F. Soltani, F. Hagparast, S. & Abkari, A. 2015. Heavy metal pollution assessment in relations to sediment properties in the costal sediments of the southern Caspian Sea. Marine Pollution Bulletin92, 237-243.
  • Copat, Ch., Bell, F., Castaing, M., Fallico, R.& Sciacca, M. 2012. Heavy metals and their compounds concentrations is fish form Sicily (Mediterranean Sea) and evaluation of possible health risks to consumers Bulletin Environmental Contamination and Toxicology 88, 78-83.
  • Evans, L.J. 1989. Chemistry of metal retention by soils. Environmental Science & Technology 23(9), 1047-1056.
  • Florence, T.M. & Batley, G.E. 1980. Chemical speciation in natural waters. Critical Reviews in Analytical Chemistry 9(3), 219-296.
  • Gao, X. & Chen, C.T.A. 2021. Heavy metal pollution status in surface sediments of the coastal Bohai Bay Water Resistant 46, 1901-1911.
  • Ginsberg, G. & Toal, B. 2009. Quantitate approach for incorporating methyl mercury risk and omega-3 fatty acid benefits in developing species-specific fish consuming advice. Environmental Health Perspectives117, 267-275.
  • Glasby, G.P., Szefer, P., Geldon, J. & Warzocha, J. 2003. Heavy-metal pollution of sediments from Szczecin Lagoon and the Gdansk Basin, Poland. Science of the Total Environment 330, 249-269.
  • Guéguen, C. & Dominik, J. 2003. Partitioning of trace metals between particulate, colloidal and truly dissolved fractions in a polluted river: the upper Vistula River (Poland).Applied Geochemistry 18, 457-470.
  • Haseler, M., Balciunas, A., Hauk, R., Sabaliauskaite, V., Chubarenko, I., Ershova, A. & Schernewski, G. 2020. Marine litter pollution in Baltic Sea beaches - application of the sand Rake Method. Frontiersin Environmental Science.
  • HELCOM. 2010. Ecosystem Health of the Baltic Sea 2003-2007: HELCOM Initial Holistic Assessment. Baltic Sea Environment Proceedings 122.
  • Horowitz, A.J. 1991. A Primer on Sediment-Trace Element Chemistry. Michigan, Lewis. 1-134.
  • Kałmykow-Piwińska, A.& Falkowska, E. 2020. Morphodynamic conditions of heavy metal concentration in deposits of the Vistula River valley near Kępa Gostecka (central Poland). Applied Geomorphology12, 1036-1051.
  • Magdaleno, A.,de Cabo, L., Arreghini, S.& Salinas, C. 2014. Assessment of heavy metal contamination and water quality in an urban river from Argentina. Brazilian Journal Aquatic Science and Technology 18(1), 113-120.
  • Majewski, W. 2013. Sustainable development of the lower Vistula. Meteorology, Hydrology and Water Management1, 33-37.
  • Martin, C.W. 2004. Heavy metal storage in near channel sediments of the Lahn River, Germany. Geomorphology 261, 275-85.
  • Martin, C.W. 2015. Trace metal storage in recent floodplain sediments along the Dill River, Central Germany. Geomorphology 235, 52-62.
  • Meybeck, M. 2013. Heavy metal contamination in rivers across the globe: an indicator of complex interaction between societies and catchments. Proceedings of H04, IAHS-IAPSO-IASPI Assembly, Gothenburg, 361, 3-17.
  • Miller, J.R. 1997. The role of fluvial geomorphic processes in the dispersal of heavy metals and their compounds from mine sites. Journal of Geochemical Exploration58, 101-18.
  • Nikulina, A. & Dullo, W.Ch. 2009. Eutrophication and heavy metal pollution in the Flensburg Fjord: a reassessment after 30 years. Marine Pollution Bulletin 58, 905-915.
  • Ministry of the Environment. 2016. Regulation Ministry of the Environment of 21 July 2016 on the method of qualifying the status of surface water bodies and environmental quality standards for priority substances. Limit values of water quality indicators from the group of substances harmful to the aquatic environment relating to bodies of surface waters of all categories. (DzU 2016, poz. 1187).
  • Radke, B., Wasik, A., Jewell, L., Pączek, U., Gałuszka, A. & Namieśnik, J. 2012. The seasonal changes of organotin compounds in water and sediments samples collected from the area of Port of Gdynia. Science of the Total Environment 441, 57-66.
  • Radke, B., Piketh, S., Wasik, A., Namieśnik, J., Dembska, G. & Bolałek, J. 2013. Aspects of pollution in Gdansk and Gdynia harbours at the coastal zone of the south Baltic Sea. The International Journal on Marine Navigation and Safety of Sea Transportation 7(1), 11-18.
  • Santoyo, E., Santoyo-Gutiérrez, S., Verma, S.P. 2000. Trace analysis of heavy metals and their compounds in groundwater samples by ion chromatography with post-column reaction and ultraviolet visible detection. Journal of Chromatography 884 (1-2), 229-241.
  • Santos Bermejo, J.C., Beltran, R.&Gomez Ariza, J.L. 2003. Spatial variations of heavy metals and their compounds contamination in sediments from Odiel river (Southwest Spain). Environment29, 69-77.
  • Souza, A.M., Salviano, A.A., Melo, J.F.B., Felix, W.S., Belem, C.S. & Ramos, P.N. 2016. Seasonal study of concentration of heavy metals and their compounds in waters lower Sao Francisco River basin. Brazilian Journal of Biology76(4), 967-974.
  • Szlinder-Richert, J., Barsk, I., Mazerski, J.& Usydus, Z. 2009. PCBs in fish from the southern Baltic Sea: levels, bioaccumulation features, and temporal trends during the period from 1997 to 2006. Marine Pollution Bulletin 58, 85-92.
  • Tarley, C.R.T. & Arruda, M.A.Z. 2003. Adsorventes naturais: potencialidades e aplicações da esponja natural (Luffacylindrica) na remoção de chumbo em efluentes de laboratório. Reviews in Analgesia 4, 25-31.
  • Xu, F., Tian, X., Yin, F., Zhao, Y. & Yin, H. 2016. Heavy metals and their compounds in surface sediments of the northern portion of the South China Sea shelf: distribution, contamination and sources. Environmental Science of Pollution Resistance 23, 8940-8950.
  • Yu, F.C., Fang, G.H. & Ru, X.W. 2010. Eutrophication, health risk assessment and spatial analysis of water quality in Gucheng Lake, China. Environmental Earth Science 9, 1741-1748.
  • Vallius, H. 2014. Heavy metal concentration in sediment cores from northern Baltic Sea: decline over the last two decades. Marine Pollution Bulletin 79, 359-364.
  • Zaborska, A. 2014. Antropogenic lead concentrations and source in Baltic Sea sediments based on lead isotopic composition. Marine Pollution Bulletin 84, 99-113.
  • Zalewska, T., Woroń, J., Danowska, B. & Suplińska, A. 2015. Temporalchanges Hg, Pb, Cd, Zn environmental concentrations in the southern Baltic sediments dated with 210 Pb method. Oceanologia 57, 32-43.
  • Zalewska, T. & Danowska, B. 2017. Marine environment status assessment based on macrophytobentic plants as bio-indicators of heavy metals and their compounds pollution. Marine Pollution Bulletin 118, 281-288.
  • Zohra, B.S. &Habit, A. 2016. Assessment of heavy metal contamination levels and toxicity in sediments and fishes from the Mediterranean Sea (southern coast of Safax, Tunisia). Environmental Science of Pollution Resistance 23, 13954-13963.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-35ae9c53-cdbb-46a7-a624-47de31c31d80
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