In this paper, there was investigated the content of mercury in soil, plant, water, and hydrobionts in Kyiv and in the Obukhiv district of the Kyiv region. Studied territory is characterized by high anthropogenic load. The solid waste landfill in the Obukhiv district of the Kyiv region was characterized by the highest content of Hg in soil. Hg concentration in Taraxacum officinale L. was the highest among all studied plants, hence the possibility of recommending this species for phytoremediation of mercury-polluted soils. Mercury bioaccumulation of aquatic organisms (Blicca bjoerkna L., Esox lucius L., Ceratophyllum demersum L.) was much higher than in terrestrial organisms, which indicates the significantly prevailing level of availability and accumulation of mercury for aquatic species in the water environment.

Atwell, L., Hobson, K., Welch, H., 1998. Biomagnification and bioaccumulation of mercury in an arctic marine food web: insights from stable nitrogen isotope analysis. Canadian Journal of Fisheries and Aquatic Sciences, 55: 1114–1121.

Beyersmann, D., Hartwig, A., 2008. Carcinogenic metal compounds: recent insight into molecular and cellularmechanisms. Archives of Toxicology, 82(8): 493–512.

Bolivia seeks to further knowledge of impact pf mercury. 2016. World Wide Fund for Nature. Available at: http://d2ouvy59p0dg6k.cloudfront.net/downloads/mercury_en_1810.pdf

Czarnowska, K. Milewska, A., 2000. The content of heavy metals in an indicator plant (Taraxacum officinale) in Warsaw. Polish Journal of Environmental Studies, 9(2): 125–128.

Dimitrijevic, V., Krstić, N., Stanković, M., Arsić, I., Nikolić, R., 2016. Biometal and heavy metal content in the soil-nettle (Urtica dioica L.) system from different localities in Serbia. Advanced Technologies, 5(1):17–22.

Dombaiová, R., 2005. Mercury and methylmercury in plants from differently contaminated sites in Slovakia. Plant Soil Environmental, 51(10): 456–463.

Edwards, S., MacLeod, C., Lester, J., 1998. The Bioavailability of Copper and Mercury to the Common Nettle (Urtica Dioica) and the Earthworm Eisenia Fetida from Contaminated Dredge Spoil. Water, Air, and Soil Pollution, 102: 75–90.

Fant, M., Nyman, M., Helle, E., Rudbäck, E., 2001. Mercury, cadmium, lead and selenium in ringed seals (Phoca hispida) from the Baltic Sea and from Svalbard, Environment Pollution, 111: 493–501.

Fedyushina, O., 2013. Mercury in freshwater hydrobionts. International Youth School-Seminar Geochemistry of Living Matter. Tomsk, pp. 180–182 (in Russian).

Giger, W., 2009. The Rhine red, the fish dead—the 1986 Schweizerhalle disaster, a retrospect and long-term impact assessment. Environmental Science Pollution Reseach, 16: 98–111

Gray, J., Theodorakos, P., Fey, D., Krabbenhoft, D., 2015. Mercury concentrations and distribution in soil, water, mine waste leachates, and air in and around mercury mines in the Big Bend region, Texas, USA. Environment Geochemistry and Health, 37(1): 35–48

Guidelines "Determination of mercury in production facilities, environment and biological materials". Order of the Ministry of Health of Ukraine, no. 263. Available at: https://zakon.rada.gov.ua/rada/show/v0263282-05#Text

Gworek, B., Dmuchowski, W., Baczewska-Dąbrowska, A., 2020. Mercury in the terrestrial environment: a review. Environmental Sciences Europe, 32. Available at: https://doi.org/10.1186/s12302-020-00401-x

Heise, S., Förstner, U., 2006. Risks from Historical Contaminated Sediments in the Rhine Basin. Water, Air, and Soil Pollution, 6: 625–636.

Kabata-Pendias, A. and Dudka, S., 1991. Trace metal contents of Taraxacum officinale (dandelion) as a conventional environmental indicator. Environmental and Geochemical Health, 13: 108–113.

Kabata-Pendias, A., Mukherjee, A., 2007. Trace Elements from Soil to Human, Springer-Verlag, Berlin–Heidelber, 550 pp.

Kabata-Pendias, A., 2010. Trace Elements in Soils and Plants (4th ed.), CRC Press, Boca Raton, 548 pp. https://doi.org/10.1201/b10158.

Lebedeva, N., Zimina, O., Fateev, N., Nikulina, A., Berchenko, I., Meshcheriakov, N., 2018. Mercury in Hydrobionts and Their Habitat in Grønfjorden, West Spitsbergen, in Early Springtime. Geochemistry International, 56: 332–343.

Li, S., Jia, Z., 2018. Heavy metals in soils from a representative rapidly developing megacity (SW China): levels, source identification and apportionment. Catena, 163: 414–423.

Lima, L., Egreja, F., Linhares, L., Windmoller, C., Yoshida, M., (2015) Accumulation and oxidation of elemental mercury in tropical soils. Chemosphere, 134:181–191.

Lomonte, C., Doronila, A., Gregory, D., Baker, A., Kolev, S., 2010. Phytotoxicity of biosolids and screening of selected plant species with potential for mercury phytoextraction. Journal of Hazardous Materials, 173: 494–501.

Mason, R., Choi, A., Fitzgerald, W., Hammerschmidt, C., Lamborg, C., Soerensen, A., 2012. Mercury biogeochemical cycling in the ocean and policy implications. Environmental Research, 119: 101–117.

Mercury and health. 2017. WHO. Available at: https://www.who.int/news-room/fact-sheets/detail/mercury-and-health

Mercury Emissions: The Global Context. 2019. United States Environmental Protection Agency. Available at: https://www.epa.gov/international-cooperation/mercury-emissions-global-context

Mercury in the food chain. 2020. Government of Canada. Available at: https://www.canada.ca/en/environment-climate-change/services/pollutants/mercury-environment/health-concerns/food-chain.html

Obrist, D., 2007. Atmospheric mercury pollution due to losses of terrestrial carbon pools? Biogeochemistry, 85: 119–123.

Patra, M., Sharma, A., 2000. Mercury toxicity in plants. Botanical Review, 66: 379–422. Available at: https://doi.org/10.1007/BF02868923

Petrova, S., Yurukova, L., Velcheva, I., 2013. Taraxacum officinale as a biomonitor of metals and toxic elements (Plovdiv, Bulgaria). Bulgarian Journal of Agricultural Science,19(2): 241–247.

Pickhardt, P., Folt, C., Chen, C., Klaue, B., Blum, J., 2002. Algal blooms reduce the uptake of toxic methylmercury in freshwater food webs. Proceeding of the National Academy of Science of the United States of America, 99(7): 4419–4423.

Program for the development of water management and environmental rehabilitation of water bodies in the Obukhiv district of Kyiv region until 2021. 2015. Approved by the decision of the session of the Obukhiv district council from 12.06.2015, no. 629. (in Ukrainian)

Progress reports on cadmium, mercury, copper and zinc. 1987, Baltic sea environment proceedings. Helsinki Commission, 24, 131 pp.

Raquel A., Eleazar R., 2012. Phytotoxicity of Mercury in Plants: A Review. Journal of Botany, 2012: 1–7. Available at: https://www.hindawi.com/journals/jb/2012/848614

Regulation of maximum levels of certain contaminants in foodstuffs, 2013. State hygiene rules and regulations. Order of the Ministry of Health of Ukraine, 368. Available at: http://zakon2.rada.gov.ua/laws/show/z0774-13

Sas-Nowosielska, A., Galimska-Stypa, R., Kucharski, R., Zielonka, U., Małkowski, E., Gray, L., 2008. Remediation aspect of microbial changes of plant rhizosphere in mercury contaminated soil. Environmental Monitoring and Assessment, 137(1–3):101–109

Selander, L., Svan, P., 2007. Occurrence and distribution of heavy metals in lake Poopó, Bolivia. Master thesis. Department of Chemical and Water Resources Engineering, Lund University, Lund, Sweden.

Selin, N., Jacob, D., Park, R., Yantosca, R., Strode, S., Jaeglé, L., 2007. Chemical cycling and deposition of atmospheric mercury: global constraints from observations. Journal of Geophysical Research: Atmosphere,112: 1–14.

Summary report of a workshop on phytoremediation research needs, 1994. U.S. Department of Energy. Available at: http://www.osti.gov/bridge/purl.cover.jsp;jsessionid=D72C8DD9003DCF51984EE254A6ED8BCB?purl=/10109412-BckU4U/webviewable/

Tangahu, B., Abdullah, S., Basri, H., Idris, M., Nurina Anuar, Mukhlisin, M., 2011. A Review on Heavy Metals (As, Pb, and Hg) Uptake by Plants through. Phytoremediation International Journal of Chemical Engineering, 2011: 1–31.

Technical Background Report to the Global Mercury Assessment 2018. 2019. UN Environment. Available at: https://web.unep.org/globalmercurypartnership/technical-background-report-global-mercury-assessment-2018

The first screening in the Dnieper river basin: details. 2021. Ministry of Environmental Protection and Natural Resources of Ukraine. Available at: https://mepr.gov.ua/news/36932.html

Trachtenberg, І., Krasnokutskaya, L., Lubyanov, I., 2016. Mercury and its danger is an old and new problem. Modern Problems of Toxicology, Food and Chemical Safety, 1(2016):13–23 (in Ukrainian).

Wang, D., Qing, C., Guo, T., Guo, Y., 1997. Effects of humic acid on transport and transformation of mercury in soil-plant systems. Water Air Soil Pollution, 95: 35–43.

Zahir, F., Rizwi, S., Haq, S., Khan, R., 2005. Low dose mercury toxicity and human health. Environmental Toxicology and Pharmacology, 20(2):351–360.