Quantitative Approach to Studying Film Pollution of the Sea Surface Using Satellite Imagery

V. V. Zamshin, E. R. Matrosova, V. N. Khodaeva, O. I. Chvertkova

AEROCOSMOS Research Institute for Aerospace Monitoring, Moscow, Russian Federation

e-mail: viktor.v.zamshin@gmail.com

Abstract

Purpose. Numerous studies of various film pollutions (oil spills, surfactants etc.) are performed by means of satellite monitoring of seas and oceans. However, the problem of formal ranking the water areas of the regions under study by frequency and intensity of pollution is still unsolved. The conditions and periodicity of satellite survey can differ greatly depending on the monitoring region that determines both spatial variability of the probability of film pollution detection and the need to take this feature into consideration. Here we attempt to develop a quantitative approach to studying the sea surface film pollutions based on processing of large volumes of satellite optical and radar imagery.

Methods and Results. The concept “index of sea surface exposure to film pollutions”, dfpMON, and the method for calculating its quantitative value on a regular spatial grid are proposed. The value of dfpMON is defined as a ratio of the pollution area observed at the site to the area of the analyzed resolution elements (where detection of film pollution is theoretically possible). Within the framework of this approach, the already existing methods for analyzing the results of long-term satellite seawater pollution monitoring were improved due to taking into account the meteorological conditions and the spatial distribution of the observation amount. Having been applied, the proposed approach permitted to study spatial distribution of the non-biogenic film pollutions in the northern part of the Black Sea; they were detected resulting from interpretation of 4428 satellite images obtained in 2019 by the Landsat-8, Sentinel-2A/B and Sentinel-1A/B satellites (2499 cases of pollution processed). The average value of the dfpMON index was 0.012%. Three regions, where the dfpMON values exceeded the average one by more than 30 times were identified.

Conclusions. The example of a site in the northern Black Sea has shown the possibility of obtaining representative information products of satellite oceanography, which quantitatively characterize spatial variability of the sea surface film pollution recorded during the long-term episodes of satellite monitoring.

Keywords

Earth remote sensing, sea surface, film pollutions, oil slicks, optical survey, multispectral imagery, radar imagery, satellite oceanography, Black Sea

Acknowledgements

The study was carried out within the framework of the state task No. 0588-2019-0030, and agreement No. 075-15-2020-776.

Original russian text

Original Russian Text © V. V. Zamshin, E. R. Matrosova, V. N. Khodaeva, O. I. Chvertkova, 2021, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 37, Iss. 5, pp. 610-622 (2021)

For citation

Zamshin, V.V., Matrosova, E.R., Khodaeva, V.N. and Chvertkova, O.I., 2021. Quantitative Approach to Studying Film Pollution of the Sea Surface Using Satellite Imagery. Physical Oceanography, 28(5), pp. 567-578. doi:10.22449/1573-160X-2021-5-567-578

DOI

10.22449/1573-160X-2021-5-567-578

References

  1. Ivanov, A.Yu., 2007. Slicks and Oil Films Signatures on Syntetic Aperture Radar Images. Issledovanie Zemli iz Kosmosa, (3), pp. 73-96 (in Russian).
  2. Lavrova, O.Yu. and Mityagina, M.I., 2013. Satellite Monitoring of Oil Slicks on the Black Sea Surface. Izvestiya, Atmospheric and Oceanic Physics, 49(9), pp. 897-912. https://doi.org/10.1134/S0001433813090107
  3. Fingas, M. and Brown, C., 2013. Oil Spill Remote Sensing. In: J. Orcutt, ed., 2013. Earth System Monitoring. New York: Springer, pp. 337-388. https://doi.org/10.1007/978-1-4614-5684-1_15
  4. Ivanov, A.Yu., Kucheiko, A.A., Filimonova, N.A., Kucheiko, A.Yu., Evtushenko, N.V., Terleeva, N.V. and Uskova, A.A., 2017. Spatial and Temporal Distribution of Oil Spills in the Black Sea and the Caspian Sea Based on SAR Images: Comparative Analysis. Issledovanie Zemli iz Kosmosa, (2), pp. 13-25. https://doi.org/10.7868/S0205961417020038 (in Russian).
  5. Skrunes, S., Johansson, A.M. and Brekke, C., 2019. Synthetic Aperture Radar Remote Sensing of Operational Platform Produced Water Releases. Remote Sensing, 11(23), 2882. https://doi.org/10.3390/rs11232882
  6. Ivonin, D., Brekke, C., Skrunes, S., Ivanov, A. and Kozhelupova, N., 2020. Mineral Oil Slicks Identification Using Dual Co-polarized Radarsat-2 and TerraSAR-X SAR Imagery. Remote Sensing, 12(7), 1061. https://doi.org/10.3390/rs12071061
  7. Bondur, V.G., 2011. Aerospace Methods and Technologies for Monitoring Oil and Gas Areas and Facilities. Izvestiya, Atmospheric and Oceanic Physics, 47(9), pp. 1007-1018. https://doi.org/10.1134/S0001433811090039
  8. Mityagina, M.I., Lavrova, O.Yu. and Bocharova, T.Yu., 2015. Satellite Monitoring of Oil Pollution of the Sea Surface. Sovremennye Problemy Distantsionnogo Zondirovaniya Zemli iz Kosmosa, 12(5), pp. 130-149. Available at: http://d33.infospace.ru/d33_conf/sb2015t5/130%E2%80%93149.pdf [Accessed: 10 March 2021] (in Russian).
  9. Ivanov, A.Yu. and Zatyagalova, V.V., 2008. A GIS Approach to Mapping Oil Spills in a Marine Environment. International Journal of Remote Sensing, 29(21), pp. 6297-6313. https://doi.org/10.1080/01431160802175587
  10. Bulycheva, E.V., Kostianoy, A.G. and Krek, A.V., 2016. Interannual Variability of Sea Surface Oil Pollution in the Southeastern Baltic Sea in 2004−2015. Sovremennye Problemy Distancionnogo Zondirovaniya Zemli iz Kosmosa, 13(4), pp. 74-84. https://doi.org/10.21046/2070-7401-2016-13-4-74-84 (in Russian).
  11. Ivanov, A. and Matrosovа, E., 2019. Technogenically Рrovoked Seepage Activity in the Northwestern Part of the Black Sea According to Data from Space. Ecology and Industry of Russia, 23(8), pp. 57-63. https://doi.org/10.18412/1816-0395-2019-8-57-63 (in Russian).
  12. Mityagina, M. and Lavrova, O., 2016. Satellite Survey of Inner Seas: Oil Pollution in the Black and Caspian Seas. Remote Sensing, 8(10), 875. https://doi.org/10.3390/rs8100875
  13. Carpenter, A., 2019. Oil Pollution in the North Sea: the Impact of Governance Measures on Oil Pollution over Several Decades. Hydrobiologia, 845(1), рр. 109-127. https://doi.org/10.1007/s10750-018-3559-2
  14. Ferraro, G., Meyer‐Roux, S., Muellenhoff, O., Pavliha, M., Svetak, J., Tarchi, D. and Topouzelis, K., 2009. Long Term Monitoring of Oil Spills in European Seas. International Journal of Remote Sensing, 30(3), pp. 627-645. https://doi.org/10.1080/01431160802339464
  15. Lavrova, O.Yu., Mityagina, M.I. and Kostianoy, A.G., 2016. Satellite Methods for Detecting and Monitoring Marine Zones of Ecological Risk. Moscow: SRI RAS, 334 p. Available at: http://www.iki.rssi.ru/books/2016lavrova.pdf [Accessed: 10 March 2021] (in Russian).
  16. Bondur, V.G., Ivanov, V.A., Vorobiev, V.E., Dulov, V.A., Dolotov, V.V., Zamshin, V.V., Kondratiev, S.I., Lee, M.E. and Malinovsky, V.V., 2020. Ground-to-Space Monitoring of Anthropogenic Impacts on the Coastal Zone of the Crimean Peninsula. Physical Oceanography, 27(1), pp. 95-107. https://doi.org/10.22449/1573-160X-2020-1-95-107
  17. Kruglyakova, R.P., Kruglyakova, M.V. and Shevtsova, N.T., 2009. Geological-Geochemical Characterization of Hydrocarbon Natural Shows in the Black Sea. Geology and Mineral Resources of World Ocean, (1), pp. 37-51. Available at: https://cyberleninka.ru/article/n/geologo-geohimicheskaya-harakteristika-estestvennyh-proyavleniy-uglevodorodov-v-chernom-more/viewer [Accessed: 15 March 2021] (in Russian).
  18. Bondur, V.G., Zamshin, V.V., Zamshina, A.Sh. and Vorobyev, V.E., 2020. Registering from Space the Features of Deep Wastewater Outfalls into Coastal Water Areas Due to Discharge Collector Breaks. Izvestiya, Atmospheric and Oceanic Physics, 56(9), pp. 979-988. https://doi.org/10.1134/S0001433820090066
  19. Glumov, I.F., Gulev, V.L., Senin, B.V. and Karnaukhov, S.M., 2014. Regional Geology and Prospects of Oil and Gas Content in the Black Sea Deep-Water Basin and Adjacent Shelf Zones: in two volumes. Part 1]. Moscow: Izdatel'skiy dom Nedra, 273 p. (in Russian).
  20. Nemirovskaya, I.A., Onegina, V.D. and Konovalov, B.V., 2017. Hydrocarbons in the Suspended Matter and the Bottom Sediments in Different Regions of the Black Sea Russian Sector. Physical Oceanography, (4), pp. 46-58. https://doi.org/10.22449/1573-160X-2017-4-46-58
  21. Krestenitis, M., Orfanidis, G., Ioannidis, K., Avgerinakis, K., Vrochidis, S. and Kompatsiaris, I., 2019. Oil Spill Identification from Satellite Images Using Deep Neural Networks. Remote Sensing, 11(15), 1762. https://doi.org/10.3390/rs11151762

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