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This work aimed to evaluate groundwater potability for the population through geochemical assessment methods on the example of aquifers in Krasnodar city. In 2016 and 2019, on the territory of Krasnodar city (Krasnodar region, Russian Federation), a detailed geochemical analysis of groundwater quality was performed based on a total of 6000 samples, 3000 samples per each year. Samples were taken from 30 wells located at depths of up to 450 m in the layers of Anthropogen and Neogene stages. Quantitative analysis of wells according to the average water quality parameters showed that in 15 wells, the water condition met the MAC (maximum allowable concentration) standards in all layers. Water abundance between the layers of the Quaternary and Cimmerian stages is seven times as different (p ≤ 0.001) towards the latter, the hardness between the same horizons is ten times as different (p ≤ 0.001) towards the Quaternary stage and three times as different (p ≤ 0.05) in terms of solid residue. Thus, the water hardness and water abundance index vary significantly between the vertical layers. A strong positive correlation between the solid residue and the hardness values (Pearson correlation 0.93, p ≤ 0.05), and a negative correlation between water abundance and solid residue values (Pearson correlation - 0.83, p ≤ 0.05), as well as between the hardness and water abundance values (Pearson correlation - 0.81, p ≤ 0.05) was recorded. These findings can be used for regions with similar deposits of rocks and aquifers.
Wydawca
Czasopismo
Rocznik
Tom
Strony
34--43
Opis fizyczny
Bibliogr. 37 poz., rys., tab., wykr.
Twórcy
autor
- M. Auezov South Kazakhstan University, Research Laboratory: Adsorption and Filtration Purification of Gases and Liquids, 5 Tauke khan Avenue, 160012 Shymkent, Kazakhstan
autor
- Federal State Budgetary Institution “Centre for Strategic Planning and Management of Biomedical Health Risks” of the Federal Medical and Biological Agency, Moscow, Russia
autor
- Kuban State Technological University, Department of Cadastre and Geoengineering, Kuban, Russia
- Kuban State Agrarian University, Department of Geodesy, Kuban, Russia
Bibliografia
- ARENDAL U.G. 2002. A world of salt: Total global saltwater and freshwater estimates [online]. Vital Water Graphics. [Access 25.11.2021]. Available at: https://www.grida.no/resources/5808
- BELITZ K., JURGENS B.C., JOHNSON T.D. 2016. Potential corrosivity of untreated groundwater in the United States (No. 2016-5092). Scientific Investigations Report 2016-5092. US Geological Survey pp. 16. DOI 10.3133/sir20165092.
- BINDAL S., KUMAR A., MALLICK J., SHASHTRI S., KUMAR P., SINGH C.K. 2020. Geochemical, topographical, and meteorological controls on groundwater arsenic contamination in Sharda River Basin of Uttar Pradesh, India. Journal of Climate Change. Vol. 6. Iss. 2 p. 71–87. DOI 10.3233/JCC200013.
- BINDAL S., SINGH C.K. 2019. Predicting groundwater arsenic contamination: Regions at risk in highest populated state of India. Water Research. Vol. 159 p. 65–76. DOI 10.1016/j.watres.2019.04.054.
- BOGAS J.A., GOMES A. 2015. Non-steady-state accelerated chloride penetration resistance of structural lightweight aggregate concrete. Cement and Concrete Composites. Vol. 60 p. 111–122. DOI 10.1016/j.cemconcomp.2015.04.001.
- BRADY K.B.C., KANIA T., SMITH M.W., HORNBERGER R.J. 1998. Coal mine drainage prediction and pollution prevention in Pennsylvania. Pennsylvania Department of Environmental Protection. [Access 25.11.2021]. Available at: https://wvmdtaskforce.files.wordpress.com/2016/01/00-pbrady.pdf
- COZZARELLI I.M., SKALAK K.J., KENT D.B., ENGLE M.A., BENTHEM A., MUMFORD A.C., ..., JOLLY G.D. 2017. Environmental signatures and effects of an oil and gas wastewater spill in the Williston Basin, North Dakota. Science of the Total Environment. Vol. 579 p. 1781–1793. DOI 10.1016/j.scitotenv.2016.11.157.
- CRAVOTTA C.A., SHERROD L., GALEONE D.G., LEHMAN W.G., ACKMAN T.E., KRAMER A. 2017. Hydrological and geophysical investigation of streamflow losses and restoration strategies in an abandoned mine lands setting. Environmental and Engineering Geoscience. Vol. 23. Iss. 4 p. 243–273. DOI 10.2113/gseegeosci.23.4.243.
- DEMCHENKO O.P., LARIONOVA L.V., SKLYARENKO O.В. 2018. Sanitarno-gigiyenicheskiye problemy vodnykh resursov krasnodarskogo kraya i g. Krasnodara. V: Ekologiya Rechnykh Landshaftov [Sanitary and hygienic issues of water resources in Krasnodar Krai and the city of Krasnodar. In: Ecology of river landscapes]. Ed. N.N. Mamas. Krasnodar. KubGAU p. 52–60.
- DOMAGALSKI J.L., JOHNSON H.M. 2011. Subsurface transport of orthophosphate in five agricultural watersheds, USA. Journal of Hydrology. Vol. 409. Iss. 1–2 p. 157–171. DOI 10.1016/j.jhydrol.2011.08.014.
- ELUMALAI V, NWABISA D.P., RAJMOHAN N. 2019. Evaluation of high fluoride contaminated fractured rock aquifer in South Africa - Geochemical and chemometric approaches. Chemosphere. Vol. 235 p. 1–11. DOI 10.1016/j.chemosphere.2019.06.065.
- EPA 2014. Framework for human health risk assessment to inform decision making framework for human health risk assessment to inform decision making [online]. U.S. Environmental Protection Agency pp. 63. [Access 10.12.2020]. Available at: https://www.epa.gov/sites/production/files/2014-12/documents/hhra-frame-work-final-2014.pdf
- HAASE K.B., KOZAR M.D., MCADOO M.A., CASILE G.C., STEFFY L., RISSER D.W. 2019. Dataset of trace dissolved hydrocarbons in surface water and groundwater in North Dakota, Pennsylvania, Virginia, and West Virginia between 2014 and 2017. Reston. U.S. Geological Survey. DOI 10.5066/P9RDPWXO.
- HARKNESS J.S., DARRAH T.H., WARNER N.R., WHYTE C.J., MOORE M.T., MILLOT R., KLOPPMANN W., JACKSON R.B., VENGOSH A. 2017. The geochemistry of naturally occurring methane and saline groundwater in an area of unconventional shale gas development. Geochimica et Cosmochimica Acta. Vol. 208 p. 302–334. DOI 10.1016/j.gca.2017.03.039.
- HEISIG P.M., SCOTT T.M. 2013. Occurrence of methane in groundwater of south-central New York State, 2012-systematic evaluation of a glaciated region by hydrogeologic setting. Denver, Colorado. US Department of the Interior, US Geological Survey. ISSN 2328- 0328 pp. 32.
- KOCINA P. 1997. Body composition of spinal cord injured adults. Sports Medicine. Vol. 23 p. 48–60. DOI 10.2165/00007256-199723010-00005.
- KOZAR M.D., MCCOY K.J., BRITTON J.Q., BLAKE JR. B.M. 2017. Hydrogeology, groundwater flow, and groundwater quality of an abandoned underground coalmine aquifer, Elkhorn Area, West Virginia. Cheat Lake. West Virginia Geological and Economic Survey. ISSN 0363-1052 pp. 103.
- LEKOMTSEV A.V., ILIUSHIN P.Y., KOROBOV G.Y. 2020. Modeling and proving of design solutions for the reconstruction of treatment facility of oil and water [online]. Periódico Tchê Química. Vol. 17. Iss. 35 p. 269–282. [Access 25.11.2021]. Available at: http://www.deboni.he.com.br/arquivos_jornal/2020/35/24_LE-KOMTSEV_pgs_269_281.pdf
- Minprirody Rossii 2012. Rekomendatsii R 52.24.353-2012. Otbor prob poverkhnostnykh vod sushi i ochishchennykh stochnykh vod [Document R 52.24.353-2012. Sampling of surface water and purified waste water] [online]. Ministerstvo prirodnykh resursov i ekologii Rossiyskoy Federatsii. [Access 15.11.2021]. Available at: https://files.stroyinf.ru/Data2/1/4293792/4293 792809.htm
- MOLOFSKY L.J., CONNOR J.A., WYLIE A.S., WAGNER T., FARHAT S.K. 2013. Evaluation of methane sources in groundwater in northeastern Pennsylvania. Groundwater. Vol. 51. Iss. 3 p. 333–349. DOI 10.1111/gwat.12056.
- MURPHY M.A., SALVADOR A. 1999. International stratigraphic guide - an abridged version. Episodes. Vol. 22. Iss. 4 p. 255–272. [Access 10.12.2020]. Available at: https://www.idigbio.org/wiki/images/7/7f/255-271_Murphy_pdf
- NAGALEVSKY Y.Y., NAGALEVSKY E.Y., CHUPRINA S.T. 2010. Meliorativno-vodokhozyaystvennyy kompleks basseyna reki Kubani [Reclamation and water management complex of the Kuban river basin]. Zashchita okruzhayushchey sredy v neftegazovom komplekse. Vol. 9 p. 78–84. [Access 25.11.2021]. Available at: https://www.elibrary.ru/item.asp?id=15236595
- NEGI P., MOR S., RAVINDRA K. 2020. Impact of landfill leachate on the groundwater quality in three cities of North India and health risk assessment. Environment, Development and Sustainability. Vol. 22 p. 1455–1474. DOI 10.1007/s10668-018-0257-1.
- NGUYEN C.K., CLARK B.N., STONE K.R., EDWARDS M.A. 2011. Role of chloride, sulfate, and alkalinity on galvanic lead corrosion. Corrosion. Vol. 67. Iss. 6 p. 065005-1–065005-9. DOI 10.5006/1.3600449.
- OREM W., VARONKA M., CROSBY L., HAASE K., LOFTIN K., HLADIK M., ..., COZZARELLI I. 2017. Organic geochemistry and toxicology of a stream impacted by unconventional oil and gas wastewater disposal operations. Applied Geochemistry. Vol. 80 p. 155–167. DOI 10.1016/j.apgeochem.2017.02.016.
- Postanovleniye ot 28 yanvarya 2021 goda No. 2 Ob utverzhdenii sanitarnykh pravil i norm SanPiN 1.2.3685-21 “Gigiyenicheskiye normativy i trebovaniya k obespecheniyu bezopasnosti i (ili) bezvrednosti dlya cheloveka faktorov sredy obitaniya” [Regulation dated January 28, 2021 No. 2 On the approval of sanitary rules and norms SanPiN 1.2.3685-21 “Hygienic standards and requirements for ensuring the safety and (or) harmlessness of environmental factors for humans”]. Glavnyy gosudarstvennyy sanitarnyy vrach Rossiyskoy Federatsii. [Access 10.12.2020]. Available at: https://docs.cntd.ru/document/573500115?mar-ker=6540IN
- RAPANT S., CVEČKOVÁ V., FAJČÍKOVÁ K., DIETZOVÁ Z., STEHLÍKOVÁ B. 2017. Chemical composition of groundwater/drinking water and oncological disease mortality in Slovak Republic. Environmental Geochemistry and Health. Vol. 39. Iss. 1 p. 191–208. DOI 10.1007/s10653-016-9820-6.
- RAPANT S., FAJČÍKOVÁ K., CVEČKOVÁ V., ĎURŽA A., STEHLÍKOVÁ B., SEDLÁKOVÁ D., ŽENIŠOVÁ Z. 2015. Chemical composition of groundwater and relative mortality for cardiovascular diseases in the Slovak Republic. Environmental Geochemistry and Health. Vol. 37. Iss. 4 p. 745–756. DOI 10.1007/s10653-015-9700-5.
- RENOCK D., LANDIS J.D., SHARMA M. 2016. Reductive weathering of black shale and release of barium during hydraulic fracturing. Applied Geochemistry. Vol. 65 p. 73–86. DOI 10.1016/j.apgeochem.2015.11.001.
- RÉVÉSZ K.M., BREEN K.J., BALDASSARE A.J., BURRUSS R.C. 2010. Carbon and hydrogen isotopic evidence for the origin of combustible gases in water-supply wells in north-central Pennsylvania. Applied Geochemistry. Vol. 25. Iss. 12 p. 1845–1859. DOI 10.1016/j.apgeochem.2010.09.011.
- ROSBORG I. 2015. Drinking water minerals and mineral balance importance, health significance, safety precautions. Switzerland. Springer. ISBN 978-3-030-18034-8 pp. 175.
- SILVA E.B., DA ROCHA J.R.C. 2020. Avaliação antrópica no litoral Paranaense através da determinação da concentração do íon fosfato em recursos hídricos [Anthropic evaluation in the Paraná coast through the ion phosphate concentration determination in water resources]. Periódico Tchê Química. Vol. 17. Iss. 35 p. 293– 303. [Access 25.11.2021]. Available at: http://www.deboni.he.com.br/ccount/click.php?id=929
- SKEVAS T. 2020. Evaluating alternative policies to reduce pesticide groundwater pollution in Dutch arable farming. Journal of Environmental Planning and Management. Vol. 63. Iss. 4 p. 733–750. DOI 10.1080/09640568.2019.1606618.
- SVITOCH A.A. 2016. Polozheniye v razrezakh Bol’shogo Kaspiya nizhnikh granits yarusov verkhnego pliotsena i kvartera Mezhdunarodnoy stratigraficheskoy shkaly i paleogeogra-ficheskiye sobytiya [The position in the Greater Caspian Sea sections of the lower layers of the Upper Pliocene and the Quarternary of the International Stratigraphic Scale and Paleogeographical events] [online]. Byulleten’ Moskovskogo obshchestva ispytateley prirody. Otdel geologicheskiy. Vol. 91 Iss. 2–3 p. 63–73. [Access 25.11.2021]. Available at: https://cyberleninka.ru/article/n/polozhenie-v-razrezah-bol-shogo-kaspiya-nizhnih-granits-yarusov-verhnego-pliotsena-i- kvartera-mezhdunarodnoy-stratigraficheskoy-shkaly-i
- TORKUNOV A.V., ORLOV A.A., CHECHEVISHNIKOV A.L., ALEKSEENKOVA A.S., BORISHPOLETS K.P., KRYLOV A. V., ..., CHERNIAVSKY S.I. 2013. Problema presnoy vody. Global’nyy kontekst politiki Rossii [The problem of fresh water. The global context of Russia’s policy] [online]. Yezhegodnik Instituta mezhdunarodnykh issledovaniy Moskovskogo gosudarstvennogo instituta mezhdu-narodnykh otnosheniy (Universiteta) Ministerstva inostrannykh del Rossiyskoy Federatsii. Vol. 1. Iss. 3 p. 8–65. [Access 10.12.2020]. Available at: https://www.elibrary.ru/item.asp? id=21134567
- WHO 2007. Guidelines for drinking-water quality. Fourth edition incorporating the first addendum. Geneva. World Health Organization. ISBN 978-92-4-154995-0 pp. 631.
- YAN B., STUTE M., PANETTIERI JR. R.A., ROSS J., MAILLOUX B., NEIDELL M.J., SOARES L., HOWARTH M., LIU X., SABERI P., CHILLRUD S.N. 2017. Association of groundwater constituents with topography and distance to unconventional gas wells in NE Pennsylvania. Science of the Total Environment. Vol. 577 p. 195–201. DOI 10.1016/j.scitotenv.2016.10.160.
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-d98ab6f3-ca33-4f9e-91a9-7dd632bb6eeb