Abstract
This chapter is devoted to examples of testing of nature-like biogeochemical technologies for recultivation of disturbed and polluted soils of impacted arctic ecosystems in the face of increasing continentality of the climate. It has been demonstrated that the main factor in the disturbance of tundra soils on the Yamal Peninsula, Russia—leading to the loss of pasture areas due to formation of sand outcrops—is their overloading with deer herds. Man-made violations of soils associated with the development of hydrocarbon deposits are local in nature. Some examples of in situ and in vitro applications of biogeochemical technologies for reclamation of disturbed and polluted tundra soils, as well as reclamation of pyrogenic and hydrocarbon-contaminated soils in other gas production regions, are given.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Abdusamatov, K. I. (2011). Two-centuries decrease of solar constant leads to the unbalanced thermal budget of the earth and small ice age. In Solar and solar–terrestrial physics—2011. Proceedings of the XV all-Russian annual conference on physics of the sun. St. Petersburg: Main (Pulkovskaya) Astronomical Observatory of RAS, pp. 295–298.
Abdusamatov, K. I. (2014). The long-term negative average annual power balance of the earth will lead to the small ice age. In Solar and solar–terrestrial physics—2014. Proceedings of the XVIII all-Russian annual conference with the international participation. St. Petersburg: Main (Pulkovskaya) Astronomical Observatory of RAS, pp. 3–6.
Abdusamatov, K. I. (2017). Lunar observatory for climate researches in the epoch of deep cooling. In Solar and solar–terrestrial physics—2017. Proceedings of the XXI all-Russian annual conference on physics of the sun. St. Petersburg: Main (Pulkovskaya) Astronomical Observatory of RAS, pp. 3–6
Akopova, G. S. (2008). Biopreparation cleaning of technogenic environments contaminated by hydrocarbons. Gas Industry, 6, 69–71.
Alekseev, A. O., & Bashkin, V. N. (2017). NMR C13 measurements for assessing humates from tundra peats. In V. Bashkin (Ed.), Ecological and biogeochemical cycling in impacted polar ecosystems (Environmental remediations, technologies, regulations and safety series) (pp. 101–128). New York: Nova Science.
Andreychik, M. F., & Mongush, M. M. (2009). Peculiarities of continentality index distribution in the Tuva mountain area. Herald of the Tyvinsky State University, 2, 50–53.
Anisimov, M. V., Byshev, V. I., Zalesny, V. B., Moshonkin, S. N., Neyman, V. G., Romanov, Y. A., & Serykh, I. V. (2012). About interdecade variability of climatic characteristics of the ocean and atmosphere in the region of Northern Atlantic. Modern Problems of Remote Sounding of the Earth from Space, 9(2), 304–311.
Arabskii, A. K., Arno, O. B., Galiulin, R. V., & Bashkin, V. N. (2014). Express assessment of recultivation efficiency of disturbed tundra soils in natural gas production area. In International Gas Union Research Conference (IGRC 2014). Gas innovations inspiring clean energy. Copenhagen. 17–19 September 2014. 1, pp. 858–862.
Archibald, D. (2007). Climate outlook to 2030. Energy and Environment, 5(18), 615–619.
Arno, O. B., Arabsky, A. K., Bashkin, V. N., Galiulin, R. V., Galiulina, R. A., Maklyuk, O. V., & Priputina, I. V. (2013). Method of control of recultivation efficiency of the disturbed tundra soils of different granulometric composition by means of the analysis of dehydrogenase activity. Russian Union patent 2491137.
Arno, O. B., Arabsky, A. K., Bashkin, V. N., Galiulin, R. V., Alekseev, A. O., Galiulina, R. A., Maltseva, A. N., Yamnikov, S. A., Nikolaev, D. S., & Murzagulov, V. R. (2017a). Method of receiving of potassium humate from local peats of the Yamal-Nenets Autonomous Okrug. Russian Union patent 2610956.
Arno, O. B., Arabsky, A. K., Bashkin, V. N., Galiulin, R. V., Galiulina, R. A., Alekseev, A. O., Salbiev, T. Kh.-M., & Serebryakov, E. P. (2017b). Method of assessment of recultivation efficiency by means of peat of the disturbed tundra soils with different full moisture capacity. Russian Union patent 2611159.
Arno, O. B., Arabsky, A. K., Bashkin, V. N., Galiulin, R. V., Galiulina, R. A., Alekseev, A. O., Yamnikov, S. A., Nikolaev, D. S., & Murzagulov, V. R. (2017c). Method of assessment of recultivation efficiency of the disturbed tundra soils by means of introduction of local peat and potassium humate. Russian Union patent 2611165.
Bashkin, V., & Galiulin, R. (2012). “Gold time” of natural gas in “small ice age”. Neftegaz.RU, 8, 38–43.
Bashkin, V. N., & Galiulin, R. V. (2017). Climate cycling and modeling in polar areas. In Biogeochemical technologies for managing pollution in polar ecosystems (Vol. 26, pp. 95–105). Cham: Springer.
Bashkin, V. N., & Galiulin, R. V. (2018a). Innovative biogeochemical technology in the gas industry as green economy display. In M. Radosavljević (Ed.), Challenges of green economy. international monograph (pp. 153–160). Beograd: Ecologica.
Bashkin, V., & Galiulin, R. (2018b). Strengthening of climate continentality and adaptive recultivation of disturbed tundra soils. Neftegaz.RU, 4, 106–111.
Bashkin, V. N., Bukhgalter, E. B., Kalinina, I. E., Galiulin, R. V., & Galiulina, R. A. (2009). Recultivation of the pyrogenic soil and neutralization of gas condensate sludge by means of new biocompost. Environment Protection in an Oilgas Complex, 4, 14–17.
Bashkin, V. N., Bukhgalter, E. B., Galiulin, R. V., Kalinina, I. E., & Galiulin, R. A. (2010a). Control method for cleaning of soils contaminated by hydrocarbons and neutralization of hydrocarbon sludges by catalase activity analysis. Russian Union patent 2387995.
Bashkin, V. N., Bukhgalter, E. B., Galiulin, R. V., Kalinina, I. E., & Galiulin, R. A. (2010b). Control method for cleaning of soils contaminated by hydrocarbons and neutralization of hydrocarbon sludges by dehydrogenase activity analysis. Russian Union patent 2387996.
Bashkin, V. N., Galiulin, R. V., & Galiulina, R. A. (2011). Diagnostics of the recultivation of the soil contaminated by gas condensate and transformed by a pirogenization. Pipeline Transport [Theory and Practice], 25(3), 27–30.
Bashkin, V. N., Galiulin, R. V., & Alekseev, A. O. (2017a). New ecologically oriented biogeochemical technologies for reclamating damaged gas production areas. In Ecological and biogeochemical cycling in impacted polar ecosystems (pp. 129–140). New York: Nova Science.
Bashkin, V. N., Galiulin, R. V., Alekseev, A. O., Galiulina, R. A., & Maltseva, A. N. (2017b). Biogeochemical technology for disturbed tundra soils recultivation by peat and potassium humate application. In Biogeochemical technologies for managing pollution in polar ecosystems (Vol. 26, pp. 211–218). Cham: Springer.
Bogdanov, V. D., & Golovatin, M. G. (2017). Ecology–social–economic aspect of an epizooty of a reindeer on Yamal (on the example of Siberian plague). Scientific Bulletin of the Yamal-Nenets Autonomous Okrug, 94(1), 4–10.
Coronelli, T. V. (1996). Principles and intensification methods of biological degradation of hydrocarbons in the environment (review). Applied Biochemistry and Microbiology, 32(6), 579–585.
Dansgaard, W., Johnsen, S. J., Moller, J., & Longway, C. C., Jr. (1969). One thousand centuries of climatic record from Camp Century on the Greenland ice sheet. Science, 166(3903), 377–380.
Efremova, T. T., & Ovchinnikova, T. M. (2008). Seasonal oxidoreductase activity of drained peat soils in connection with hydrothermal conditions of the environment. Siberian Ecological Journal, XV(3), 441–449.
Galishev, M. A. (2017). Research of fire danger of disperse systems. Bulletin of the Voronezh Institute of SFS MES of Russia, 22(1), 17–23.
Galiulin, R. V., & Bashkin, V. N. (2017a). Activity of catalase and dehydrogenase enzymes as a tool for controlling the soil reclamation process. In Ecological and biogeochemical cycling in impacted polar ecosystems (pp. 91–100). New York: Nova Science.
Galiulin, R. V., & Bashkin, V. N. (2017b). Biogeochemical approaches for managing geoenvironmental risk of hydrocarbons pollution in disturbed soils. In Biogeochemical technologies for managing pollution in polar ecosystems (Vol. 26, pp. 185–192). Cham: Springer.
Galiulin, R. V., & Galiulina, R. A. (2014). Risk of chronic pollution of the soil gas condensate. Issues of Risk Analysis, 11(5), 26–29.
Galiulin, R. V., & Galiulina, R. A. (2015). Remediation of polar ecosystems polluted by gas condensate and oil hydrocarbons by biological preparations. Open Ecology Journal, 8(Suppl 1-M5), 40–43.
Galiulin, R. V., Mironenko, E. V., Pachepsky, Y. A., & Sokolov, M. S. (1984). Mathematical modeling of dynamics of the herbicide residues content in the soil. Agrochemistry, 6, 92–100.
Galiulin, R. V., Galiulina, R. A., Bashkin, V. N., Akopova, G. S., Listov, E. L., & Balakirev, I. V. (2010). Comparative assessment of gas condensate and oil hydrocarbons degradation in soil under effect of biological means. Agrochemistry, 10, 52–58.
Galiulin, R. V., Bashkin, V. N., Galiulina, R. A., Priputina, I. V., & Arabsky, A. K. (2013). Recultivation of disturbed tundra soils of the Taz Peninsula by means peat: Assessment of effectiveness by enzyme activity analysis. Agrochemistry, 4, 76–80.
Galiulin, R. V., Galiulina, R. A., & Bashkin, V. N. (2014). Reclamation of soil polluted by gas condensate using peat compost. Solid Fuel Chemistry, 48(5), 320–322.
Galiulin, R. V., Bashkin, V. N., Alekseev, A. O., Galiulina, R. A., & Arabsky, A. K. (2017a). Biogeochemical technology for recultivating disturbed soils of the island Bely (Kara Sea). In Ecological and biogeochemical cycling in impacted polar ecosystems (pp. 141–153). New York: Nova Science.
Galiulin, R. V., Bashkin, V. N., Alekseev, A. O., Galiulina, R. A., & Arabsky, A. K. (2017b). Innovative biogeochemical technology for recultivating disturbed soils of the Taz Peninsula. In Ecological and biogeochemical cycling in impacted polar ecosystems (pp. 155–166). New York: Nova Science.
Galiulin, R. V., Bashkin, V. N., & Galiulina, R. A. (2017c). Biogeochemical technology for monitoring of cleaning of soil polluted by gas condensate and neutralization of its sludge by means of enzyme activity analyses. In Biogeochemical technologies for managing pollution in polar ecosystems (Vol. 26, pp. 193–200). Cham: Springer.
Galiulin, R. V., Bashkin, V. N., & Galiulina, R. A. (2017d). Biogeochemical control of peat-based recultivation process of disturbed tundra soils varying in granulometric composition and full moisture capacity. In Biogeochemical technologies for managing pollution in polar ecosystems (Vol. 26, pp. 201–209). Cham: Springer.
Galiulin, R. V., Bashkin, V. N., & Galiulina, R. A. (2017f). Risk management of the environmental pollution during oil production and transport. In Ecological and biogeochemical cycling in impacted polar ecosystems (pp. 205–216). New York: Nova Science.
Golovnev, A. V., & Abramov, I. V. (2014). Deers and gas: Strategies of the Yamal development. Herald of Archeology, Anthropology and Ethnography, 27(4), 122–131.
Ivlev, A. M. (1986). Biogeochemistry. Moscow: Vyshaya Shkola. 127 pp.
Karimov, K. A., & Krymskaya, D. N. (2016). Peculiarities of the thermodynamic regime of the lower atmosphere in the central Asian region under the influence of the centers of action in the northern Atlantic. International Scientific Journal “Innovative Science”, 1(3), 35–38.
Kaurichev, I. C., Panov, N. P., Stratonovich, M. V., Grechin, I. P., Savich, V. I., Ganzhara, N. F., & Mershin, A. P. (1980). Practicum on soil science. Moscow: Kolos. 272 pp.
Kaurichev, I. C., Aleksandrova, L. N., Grechin, I. P., Panov, N. P., Poddubny, N. N., Rozov, N. N., & Stratonovich, M. V. (1982). Soil science. Moscow: Kolos. 496 pp.
Khaziev, F. K. (1976). Enzymatic activity of soils. Methodological textbook. Moscow: Nauka. 180 pp .
Khaziev, F. K., & Fatkhiev, F. F. (1981). Change of biochemical processes in soils at oil pollution and oil decomposition activation. Agrochemistry, 10, 102–111.
Khrenov, V. Y. (2011). Soils of west Siberian cryolithozone: Morphology, physicochemical properties, geochemistry. Novosibirsk: Nauka. 211 pp
Kovda, V. A. (1976). Biogeochemical cycles in the nature and their anthropogenic disturbance. In Biogeochemical cycles in biosphere. Materials of the VII plenum of SCOPE (pp. 19–85). Moscow: Nauka.
Kryazhimsky, F. V., Maklakov, K. V., Morozova, L. M., & Ektova, S. N. (2011). System analysis of biogeocenosis of the Yamal Peninsula: Imitating modeling of impact of large herd reindeer breeding on a vegetable cover. Ecology, 5, 323–333.
Listov, E. L., Akopova, G. S., & Balakirev, I. V. (2008). Technology optimization of “Bioros” preparation production on experimental installation of VNIIGAZ LLC. Protection of the Environment in Oilgas Complex, 8, 9–13.
Loginov, V. G., Ignatyeva, M. N., & Balashenko, V. G. (2017). The harm done to resources of traditional environmental management and its economic assessment. Economy of the Region, 13(2), 396–409.
Makeeva, N. A., & Neverova, O. A. (2016). The review of methods of the accelerated recultivation of the lands disturbed by coal mining. Bulletin of the Krasnoyarsk State Agricultural University, 8, 77–86.
Mustafina, A. B. (2017). Changes of the basic climatic indicators on the territory of the Republic of Tatarstan during 1966–2013. Geographical Herald, 2(41), 99–108.
Pachepsky, Y. A., Mironenko, E. V., Galiulin, R. V. & Sokolov, M. S. (1982). Statistical models of dynamics of content of pesticides and their metabolites in soils. Materials according to software of the ECM. ECOMODEL series. Pushchino: SCBR of AS USSR, 8. 44 pp.
Pavliuchuk, Z., Aseeva, I. V., & Sudnitsyn, I. I. (1982). Influence of potential (pressure) of soil moisture on dehydrogenase activity in soils. Bulletin of the Moscow University, Series 17, Soil Science, 2, 60–63.
Perevedentsev, Y. P., & Shantalinsky, K. M. (2015). Monitoring of changes of air temperature and speed of wind in the atmosphere of the northern hemisphere for the last decades. Russian Journal of Applied Ecology, 2, 3–8.
Popova, A. Y., Demina, Y. V., Ezhlova, E. B., Kulichenko, A. N., Ryazanova, A. G., Maleev, V. V., Ploskireva, A. A., Dyatlov, I. A., Timofeev, V. S., Nechepurenko, L. A., & Kharkov, V. V. (2016). The outbreak of the Siberian plague in the Yamal-Nenets Autonomous Okrug in 2016, epidemiological peculiarities. Problems of Especially Dangerous Infections, 4, 42–46.
Pystina, N. B., Baranov, A. V., Listov, E. L., & Budnikov, B. O. (2016). Improvement of technologies of recultivation of the disturbed and contaminated lands on fields of hydrocarbons of the far north. Scientific Herald of the Yamal-Nenets Autonomous Okrug, 2(91), 4–8.
Pystina, N. B., Unanyan, K. L., Ilyakova, E. E., Khokhlachev, N. S., & Luzhkov, V. A. (2017). Improvement of technologies of recultivation of landscapes on slopes in conditions of the far north. The Arctic: Ecology and Economy, 2(26), 27–34.
Radojevic, M., & Bashkin, V. N. (2006). Practical environmental analysis (textbook), 2nd ed. Cambridge: Royal Chemical Society Publications, UK. 457 pp.
Russian gas encyclopedia. (2004). Moscow: Bolshaya Rossiyskaya Entsyklopediya. 527 pp.
Sementsov, A. I. (2006). “Piksa” supercompost use for urban soils rehabilitation. Methodical recommendations. Moscow: VNIIA. 32 pp.
Sementsov, A. I., Antipov, B. V., Prokhorov, I. S., Mizgirev, N. S., & Bashkin, V. N. (2006). Use of “Piksa” supercompost for cleaning of the soils polluted by oil products. Environment Protection in an Oilgas Complex, 10, 14–18.
Shestakova, I. V. (2016). The Siberian plague doesn't forgive the mistakes: Assessment of information after outbreak on the Yamal in the summer of 2016. Journal of Infectology, 8(3), 5–27.
Skakun, A. A., & Volobuev, D. M. (2016). Contribution of changes of solar constant in calculation of insolation during the Holocene. In Solar and solar–terrestrial physics—2016. Proceedings of the XX all-Russian annual conference on physics of the sun. St. Petersburg: Main (Pulkovskaya) Astronomical Observatory of RAS, pp. 287–290.
Ten Khak Mun, Imranova, E. L., & Kirienko, O. A. (2003). Influence of the fire on a microbe complex of the soil. Soil Science, 3, 362–369.
Teranishi, Y., Kawamoto, S., Tanaka, A., Osumi, M., & Fukui, S. (1974). Induction of catalase activity by hydrocarbons in Candida tropicalis pK 233. Agricultural and Biological Chemistry, 38, 1221–1225.
Author information
Authors and Affiliations
Rights and permissions
Copyright information
© 2019 Springer Nature Switzerland AG
About this chapter
Cite this chapter
Bashkin, V.N., Galiulin, R.V. (2019). Testing of Nature-Like Biogeochemical Technologies for Recultivation of Disturbed and Polluted Soils in Impacted Arctic Ecosystems in the Face of Increasing Continentality of Climate. In: Geoecological Risk Management in Polar Areas. Environmental Pollution, vol 28. Springer, Cham. https://doi.org/10.1007/978-3-030-04441-1_8
Download citation
DOI: https://doi.org/10.1007/978-3-030-04441-1_8
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-04440-4
Online ISBN: 978-3-030-04441-1
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)