Formation of the Ecological Risk Zones in the Coastal Water Areas of the Kerch Strait

K. I. Gurov, Yu. S. Gurova, N. A. Orekhova, S. K. Konovalov

Marine Hydrophysical Institute of RAS, Sevastopol, Russian Federation

e-mail: gurovki@gmail.com

Abstract

Purpose. The paper is aimed at studying the features of hydrological and hydrochemical structure of the bottom water layer and the distribution of geochemical parameters in the bottom sediments, and also at evaluating the basic factors in formation of the redox conditions in the bottom sediments of the Kerch Strait.

Methods and Results. The Kerch Strait ecosystem was comprehensively investigated in July and September, 2020. Hydrochemical studies of the water column were carried out using the standard hydrochemical methods. The profiles of the vertical distribution of oxygen, hydrogen sulfide, oxidized and reduced forms of iron in the pore waters were obtained, and also the geochemical characteristics of bottom sediments were defined. The features of their spatial and vertical distribution were considered. The sediment columns were sampled by a hand sampler and an acrylic soil tube (its internal diameter is 60 mm) with a vacuum seal. The pore water chemical profile was obtained by the polarographic method of analysis that included a glass Au-Hg-microelectrode. Hydrochemical structure of the surface horizon waters in July was noted to be conditioned by the Black Sea water contribution, and that of the bottom horizon waters – by the Azov Sea waters. It has been established that in a summer period in the Taman Gulf surface layer, an increased content of biogenic substances took place; and the increased water temperature and salinity, as well as active oxygen consumption in the bottom water layer decreased the degree of its saturation in the central part of the gulf. As a result, this favored the Taman Gulf silting, intensive oxygen consumption for oxidizing organic matter and the development of anaerobic conditions, and the hydrogen sulfide arising already in the surface layer of bottom sediments. In September, the main contribution was made by the Black Sea waters, that promoted the bottom water saturation with oxygen and the nutrient concentration decrease by 2–3 times. At that in September, oxygen penetrated into the sediment up to 2 mm, and the hydrogen sulfide content was 3 times lower than that in July.

Conclusions. It has been revealed that the hampered water exchange in the Taman Gulf region and the accumulation of organic matter in the bottom sediments due to the inflow of a significant amount of suspended matter, resulted in a limitation of the oxygen flow to the water bottom layer, whereas the fine-dispersion character of the sediments hampered penetration of oxygen into the bottom sediments. As a result, this contributed to the Taman Gulf silting, intensive oxygen consumption for oxidizing the organic matter and the development of anaerobic conditions, and to arising of hydrogen sulfide already in the surface layer of bottom sediments. The recorded at present anoxic conditions in the sediments upper layer can result in development of the oxygen deficiency in the bottom water layer and in formation of the ecological risk zones in the ecosystem of the Kerch Strait.

Keywords

hydrological parameters, hydrochemical parameters, currents, bottom sediments, pore waters, oxygen, voltammetry, granulometric composition, organic carbon, Kerch Strait

Acknowledgements

The investigation was carried out within the framework of the state assignment of the MHI RAS on themes FNNN-2021-0005 “Complex interdisciplinary studies of oceanologic processes which determine functioning and evolution of ecosystems in the coastal zones of the Black Sea and the Sea of Azov” and FNNN-2022-0003 «Assessment of the dependence of CO2 fluxes on the surface of the Black Sea on the physico-chemical characteristics of the marine environment and obtaining characteristics of seasonal changes in fluxes», and with the support of the RFBR project No. 20-35-90103.

Original russian text

Original Russian Text © The Authors, 2022, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 38, Iss. 6, pp. 637-654 (2022)

For citation

Gurov, K.I., Gurova, Yu.S., Orekhova, N.A. and Konovalov, S.K., 2022. Formation of the Ecological Risk Zones in the Coastal Water Areas of the Kerch Strait. Physical Oceanography, 29(6), pp. 619-635. doi:10.22449/1573-160X-2022-6-619-635

DOI

10.22449/1573-160X-2022-6-619-635

References

  1. Bryantsev, V.A., 2005. Possible Ecological Consequences of the Tuzla Damb Construction (Kerch Strait). Morskoj Ehkologicheskij Zhurnal = Marine Ekological Journal, 4(1), pp. 47-50 (in Russian).
  2. Eremeev, V.N., Ivanov, V.A. and Ilyin, Yu.P., 2003. Oceanographic Conditions and Ecological Problems in the Kerch Strait. Morskoj Ehkologicheskij Zhurnal = Marine Ekological Journal, 2(3), pp. 27-40 (in Russian).
  3. Lomakin, P.D. and Borovskaya, R.V., 2006. Characteristic of Modern Condition of Currents System of Kerch Strait on Base of Satellite and Contact Observations. Issledovanie Zemli iz Kosmosa, (6), pp. 65-71 (in Russian).
  4. Fomin, V.V. and Ivanov, V.A., 2007. Coupled Modeling of Currents and Wind Waves in the Kerch Strait. Physical Oceanography, 17(5), pp. 253-268. https://doi.org/10.1007/s11110007-0020-x
  5. Orekhova, N.A. and Konovalov, S.K., 2018. Oxygen and Sulfides in Bottom Sediments of the Coastal Sevastopol Region of Crimea. Oceanology, 58(5), pp. 679-688. doi:10.1134/S0001437018050107
  6. Diaz, R.J., 2001. Overview of Hypoxia around the World. Journal of Environmental Quality, 30(2), pp. 275-281. doi:10.2134/jeq2001.302275x
  7. Meysman, F.J.R., Middelburg, J.J., Herman, P.M.J. and Heip, C.H.R., 2003. Reactive Transport in Surface Sediments. I. Model Complexity and Software Quality. Computers & Geosciences, 29(3), pp. 291-300. doi:10.1016/S0098-3004(03)00006-2
  8. Zhang, J., Gilbert, D., Gooday, A.J., Levin, L., Naqvi, S.W.A., Middelburg, J.J., Scranton, M., Ekau, W., Peña, A. [et al.], 2010. Natural and Human-Induced Hypoxia and Consequences for Coastal Areas: Synthesis and Future Development. Biogeosciences, 7(5), pp. 1443-1467. doi:10.5194/bg-7-1443-2010
  9. Losovskaya, G.V., 2011. On Indicator and Tolerant Species of Polychaetes (in the NorthWestern Black Sea). In: MHI, 2005. In: MHI, 2011. Ekologicheskaya Bezopasnost' Pribrezhnoy i Shel'fovoy Zon Morya [Ecological Safety of Coastal and Shelf Zones and Comprehensive Use of Shelf Resources]. Sevastopol: MHI. Iss. 25(1), pp. 327-334 (in Russian).
  10. Aleskerovа, A.A., Kubryakov, A.A., Goryachkin, Yu.N. and Stanichny, S.V., 2017. Propagation of Waters from the Kerch Strait in the Black Sea. Physical Oceanography, (6), pp. 47-57. doi:10.22449/1573-160X-2017-6-47-57
  11. Goryachkin, Yu.N., Kondrat’ev, S.I. and Lisichonok, A.D., 2005. Hydrological and Chemical Parameters and Water Dynamics in the Kerch Strait in March, 2004. In: MHI, 2005. In: MHI, 2014. Ekologicheskaya Bezopasnost' Pribrezhnoy i Shel'fovoy Zon Morya [Ecological Safety of Coastal and Shelf Zones and Comprehensive Use of Shelf Resources]. Sevastopol: MHI. Iss. 12, pp. 108-119 (in Russian).
  12. Kotelianets, E.A. and Konovalov, S.K., 2012. Trace Metals in Bottom Sediments of the Kerch Strait. Morskoy Gidrofizicheskiy Zhurnal, (4), pp. 50-60 (in Russian).
  13. Sapozhnikov, V.V., Kumantsov, M.I., Agatova, A.I., Arzhanova, N.V., Lapina, N.M., Roi, V.I., Stolyarskii, S.I., Bondarenko, L.G., Panov, B.N. [et al.], 2011. Complex Investigations of the Kerch Strait. Oceanology, 51(5), 896. doi:10.1134/S0001437011050146
  14. Zhugaylo, S.S., 2015. Monitoring of the Water Quality in the Kerch Strait and Pre-Strait Area of the Black Sea under Current Conditions. Monitoring Systems of Environment, 1, pp. 63-66 (in Russian).
  15. Zhugaylo, S.S., Sebakh, L.K., Shepeleva, S.M., Zagayny, N.A. and Ivanyuta, A.P., 2011. Dynamics of the Main Hydrochemical Characteristics of the Kerch Strait Water Quality in Current Conditions. In: Main Results of Complex Research in the Azov-Black Sea Basin and the World Ocean. Kerch: YugNIRO, pp. 137-146 (in Russian).
  16. Gurov, K.I., Kurinnaya, Yu.S. and Kotelyanets, E.A., 2021. Features of Accumulation and Spatial Distribution of Microelements in Bottom Sediments of the Crimea Coastal Regions. In: T. Chaplina, ed., 2021. Processes in GeoMedia Volume III. Cham, Switzerland: Springer Geology, pp. 119-130. https://doi.org/10.1007/978-3-030-69040-3_12
  17. Nemirovskaya, I.A., Zavialov, P.O. and Khramtsova, A.V., 2021. Hydrocarbons in Water and Bottom Sediments in Kerch Strait. Water Resources, 48(2), pp. 263-272. doi:10.1134/S0097807821020081
  18. Nemirovskaya, I.A., Zavyalov, P.O., Konovalov, B.V. and Khramtsova, A.V., 2020. Content and Composition of Hydrocarbons in Water and Sediments in the Area of Kerch Strait. Doklady Earth Sciences, 492(1), pp. 387-391. doi:10.1134/S1028334X20050177
  19. Tikhonova, E.A., Burdiyan, N.V. and Soloveva, O.V., 2017. The Chemical-Microbiological Characteristics of Sea Water and Bottom Sediments of the Kerch Strait and Adjacent Water Areas. Marine Biological Journal, 2(3), 75-85. doi:10.21072/mbj.2017.02.3.07 (in Russian).
  20. Klenkin, A.A. and Agapov, S.A., 2011. Dynamics of Oil Product Distributions in Water and Bottom Sediments of the Sea of Azov and the Black Sea after Ship Accidents in the Kerch Strait. Water Resources, 38(2), pp. 220-228. doi:10.1134/S0097807811020060
  21. Matishov, G.G., Inzhebeikin, Yu.I. and Savitskii, R.M., 2013. The Environmental and Biotic Impact of the Oil Spill in Kerch Strait in November 2007. Water Resources, 40(3), pp. 271284. doi:10.1134/S0097807813020048
  22. Eremeev, V.N., Konovalov, S.K. and Romanov, A.S., 1998. The Distribution of Oxygen and Hydrogen Sulfide in Black Sea Waters during Winter-Spring Period. Physical Oceanography, 9(4), pp. 259-272. https://doi.org/10.1007/BF02522712
  23. Weiss, R.F., 1970. The Solubility of Nitrogen, Oxygen and Argon in Water and Seawater. Deep Sea Research and Oceanographic Abstracts, 17(4), pp. 721-735. doi:10.1016/00117471(70)90037-9
  24. Ljutsarev, S.V., 1986. The Determination of Organic Carbon in the Sea Bottom Sediments by means of Dry Oxidation. Oceanology, 26(4), 704-708 (in Russian).
  25. Brendel, P.J. and Luther III, G.W., 1995. Development of a Gold Amalgam Voltammetric Microelectrode for the Determination of Dissolved Fe, Mn, O2, and S(-II) in Porewaters of Marine and Freshwaters Sediments. Environmental Science & Technology, 29(3), pp. 751761. doi:10.1021/es00003a024
  26. Luther III, G.W., Brendel, P.J., Lewis, B.L., Sundby, B., Lefrançois, L., Silverberg, N. and Nuzzio, D.B., 1998. Simultaneous Measurement of O2, Mn, Fe, Iˉ, and S(-II) in Marine Pore Waters with a Solid-State Voltammetric Microelectrode. Limnology and Oceanography, 43(2), pp. 325-333. doi:10.4319/lo.1998.43.2.0325
  27. Ovsyanyi, E.I., Konovalov, S.K., Mitropol'skii, A.Yu. and Kotel'yanets, E.A., 2015. Organic Carbon and Carbonates in the Recent Bottom Sediments of the Kerch Strait. Geochemistry International, 53(12), pp. 1123-1133. doi:10.1134/S0016702915120071
  28. Khrustalev, Yu.P. and Denisov, V.I., 2001. Features of Distribution of Suspended Matter and Intensity of Its Sedimentation in the Kerch Strait Region of the Black Sea. Oceanology, 41(6), pp. 907-916.
  29. Kurinnaya, Yu.S., Gurov, K.I., Zabegaev, I.A. and Orekhova, N.A., 2022. Redox Conditions and Characteristics of Bottom Sediments in the Bays of the Sevastopol Region. Ecological Safety of Coastal and Shelf Zones of Sea, (1), pp. 42-54. doi:10.22449/2413-5577-2022-1-42-54

Download the article (PDF)