Vertical nitrate migration and denitrification zones in a regional recharge area (Lwówek region, Poland)

Dragon, Krzysztof; Górski, Józef; Burghardt, Diana

doi:10.7306/gq.1647

Artykuł - szczegóły

Tytuł artykułu

Vertical nitrate migration and denitrification zones in a regional recharge area (Lwówek region, Poland)

Autorzy

Dragon Krzysztof , Górski Józef , Burghardt Diana

Treść / Zawartość

Pełne teksty:

Dragon_K_Vertical_GQ_Vol.66_No.2_2022.pdf

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Identyfikatory

DOI

10.7306/gq.1647

Warianty tytułu

Języki publikacji

Abstrakty

We examine the influence of groundwater flow patterns and denitrification on nitrate migration in a regional recharge zone. It has been shown that nitrate contamination has a different behaviour in regions where groundwater is exploited (where deep percolation of nitrate takes place) than where natural gradients exist (with no deep aquifer zone contamination). Multicomponent chemical tracers and isotopic methods were used in the investigation. A contaminant plume was discovered in shallow parts of the aquifer which percolated into deeper parts of the flow system in those regions with a downwards gradient induced by groundwater withdrawal, where the influence of denitrification was limited. Local conditions leading to intense denitrification, i.e., local changes in geological conditions (low-permeability silt intercalations), were also documented. Therefore, vertical changes in groundwater chemistry should be examined to ensure groundwater resource management and protection, as these are extremely important in regional recharge zones with a downwards gradient.

Słowa kluczowe

nitrate contamination enitrification groundwater flow pattern nitrogen isotopes sediment geochemistry

Wydawca

Państwowy Instytut Geologiczny - Państwowy Instytut Badawczy

Czasopismo

Geological Quarterly

Rocznik

2022

Tom

Vol. 66, No. 2

Strony

art. no. 15

Opis fizyczny

Bibliogr. 32 poz., rys., tab., wykr.

Twórcy

autor

Dragon Krzysztof

smok@amu.edu.pl

Adam Mickiewicz University in Poznań, Institute of Geology, Department of Hydrogeology and Water Protection, Bogumiła Krygowskiego 12, 61-680 Poznań, Poland

autor

Górski Józef

Adam Mickiewicz University in Poznań, Institute of Geology, Department of Hydrogeology and Water Protection, Bogumiła Krygowskiego 12, 61-680 Poznań, Poland

autor

Burghardt Diana

Technical University of Dresden, Institute of Groundwater Management, Department of Environmental Sciences, Bergstraße 66, 01069 Dresden, Germany

Bibliografia

1. Aravena, R., Robertson, W., 1998. Use of multiple isotope tracers to evaluate denitrification in ground water: study of nitrate from a large-flux septic system plume. Ground Water, 36: 975-982.
2. Capell, R., Bartosova, A., Tonderski, K., Arheimer, B., Pedersen, S.M., Zilans, A., 2021. From local measures to regional impacts: Modelling changes in nutrient loads to the Baltic Sea. Journal of Hydrology: Regional Studies, 36: 100867.
3. Chen, J., Tang, C., Sakura, Y., Yu, J., Fukushima, Y., 2005. Nitrate pollution from agriculture in different hydrogeological zones of the regional groundwater flow system in the North China Plain. Hydrogeology Journal, 13: 481-492.
4. Cook, P.G., Herczeg, A.L., 2000. Environmental Tracers in Subsurface Hydrology. Kluwer Academic Publishers, Boston/Dordrecht/London Council Directive 91/676/EEC of 12 December 1991 concerning the protection of waters against pollution caused by nitrates from agricultural sources.
5. Craig, L., Bahr, J., Roden, E., 2010. Localized zones of denitrification in a floodplain aquifer in southern Wisconsin, USA. Hydrogeology Journal, 18: 1867-1879.
6. Dragon, K., 2013. Grounwater nitrate pollution in the recharge zone of a regional Quaternary flow system (Wielkopolska region, Poland). Environmental Earth Sciences, 68: 2099-2109.
7. Dragon, K., 2021. Identification of groundwater conditions in the recharge zone of regionally extended aquifer system with use of water chemistry and isotopes (Lwowek region, Poland). Journal of Hydrology: Regional Studies, 34: 100787.
8. Dragon, K., Górski, J., 2009. Identification of hydrogeochemical zones in postglacial buried valley aquifer (Wielkopolska Buried Valley aquifer, Poland). Environmental Geology, 58: 859-866.
9. Dragon, K., Górski, J., 2015. Identification of groundwater chemistry origins in a regional aquifer system (Wielkopolska region, Poland). Environmental Earth Sciences, 73: 2153-2167.
10. Dragon, K., Kasztelan, D., Górski, J., Najman, J., 2016. Influence of subsurface drainage systems on nitrate pollution of water supply aquifer (Tursko well-field, Poland). Environmental Earth Sciences, 75.
11. Dunn, P., Carter, J., 2018. Publication of the second edition of the FIRMS Good Practice Guide for Isotope Ratio Mass Spectrometry. Science & Justice, 58: 467-468.
12. Einsiedl, F., Maloszewski, P., Stichler, W., 2005. Estimation of denitrification potential in a karst aquifer using the 15N and 18O isotopes of NO3-. Biogeochemistry, 72: 67-86.
13. Feast, N., Hiscock, K., Dennis, P., Andrews, J., 1998. Nitrogen isotope hydrochemistry and denitrification within the Chalk aquifer system of north Norfolk, UK. Journal of Hydrology, 211: 233-252.
14. Fryar, A.E., Macko, S.A., Mullican III, W.F., Romanak, K.D., Bennet P.C., 2000. Nitrate reduction during groundwater recharge, Southern High Plains, Texas. Journal of Contaminant Hydrology, 40: 335-363.
15. Górski, J., Dragon, K., Kaczmarek, P., 2019. Nitrate pollution in the Warta River (Poland) between 1958 and 2016: trends and causes. Environmental Science and Pollution Research, 26: 2038-2046.
16. Hojberga, A.L., Hansena, A.L., Wachniew, P., Żurek, A., Virtanenc, S., Arustiened, J., Strömqviste, J., Rankinenf, K., Refsgaard, J.C., 2017. Review and assessment of nitrate re¬duction in groundwater in the Baltic Sea Basin. Journal of Hydrology: Regional Studies, 12: 50-68.
17. Hu, L., Xu, Z., Huang, W., 2016. Development of a river-groundwater interaction model and its application to a catchment in Northwestern China. Journal of Hydrology, 543: 483-500.
18. Hutchins, M., 2012. What impact might mitigation of diffuse nitrate pollution have on river water quality in a rural catchment? Journal of Environmental Management, 109: 19-26.
19. Kaown, D., Kaown, D., Koh, E.H., Mayer, B., Kim, H., Park, D.K., Park, B.H., Lee, K.K., 2018. Application of multiple-isotope and groundwater-age data to identify factors affecting the extent of denitrification in a shallow aquifer near a river in South Korea. Hydrogeology Journal, 26: 2009-2020.
20. Karlovic, I., Posavec, K., Larva, O., Markovic, T., 2022. Numerical groundwater flow and nitrate transport assessment in alluvial aquifer of Varazdin region, NW Croatia. Journal of Hydrology: Regional Studies, 41: 101084.
21. Lasagna, M., De Luca, D.A., 2019. Evaluation of sources and fate of nitrates in the western Po plain groundwater (Italy) using nitrogen and boron isotopes. Environmental Science and Pollution Research, 26: 2089-2104.
22. Lasagna, M., De Luca, D.A., Franchino, E., 2016. The role of physical and biological processes in aquifers and their importance on groundwater vulnerability to nitrate pollution. Environmental Earth Sciences, 75.
23. Malagó, A., Bouraoui, F., Grizzetti, B., Roo, A.D., 2019. Modelling nutrient fluxes into the Mediterranean Sea. Hydrology: Regional Studies, 22: 100592.
24. Nishikiori, T., 2012. Distribution of nitrate in groundwater affected by the presence of an aquitard at an agricultural area in Chiba, Japan. Environmental Earth Sciences 67: 1531-1545.
25. Pfeiffer, S., Bahr, J., Beilfuss, R., 2006. Identification of groundwater flowpaths and denitrification zones in a dynamic floodpain aquifier. Journal of Hydrology, 325: 262-272.
26. Rivett, M., Buss, S., Morgan, P., Smith, J., Bemment, C., 2008. Nitrate attenuation in groundwater: A review of biogeochemical controlling processes. Water Research, 42: 4215-4232.
27. Sanchez-Perez, J., Bouey, C., Sauvage, S., Teissier, S., Antiguedad, I., Vervier, P., 2003. A standardised method for measuring in situ denitrification in shallow aquifers: numerical validation and measurements in riparian wetlands. Hydrology and Earth System Sciences, 7: 87-96.
28. Stock, P., Roder, S., Burghardt, D., 2021. Further optimisation of the denitrifier method for the rapid N-15 and O-18 analysis of nitrate in natural water samples. Rapid Communications in Mass Spectrometry, 35.
29. Toth, J., 1963. A theoretical analysis of groundwater flow in small drainage basins. Journal of Geophysical Research, 68: 4795.
30. Wassenaar, L., 1995. Evaluation of the origin and fate of nitrate in the Abbotsford aquifer using the isotopes of N-15 and O-18 in NO3-. Applied Geochemistry, 10: 391-405.
31. Zhang, C.Y., Zhang, S., Yin, M.Y., Ma, L.N., He, Z., Ning, Z., 2013. Nitrogen isotope studies of nitrate contamination of the thick vadose zones in the wastewater-irrigated area. Environmental Earth Sciences, 68: 1475-1483.
32. Żurek, A., Różański, K., Mochalski, P., Kuc,T., 2010. Assessment of denitrification rate in fissured-karstic aquifer near Opole (South-West Poland): combined use of gaseous and isotope tracers. Biuletyn Państwowego Instytutu Geologicznego, 441: 209-216.

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-155c2720-1490-4b3d-a57c-f04ec925c7d5