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Deep fluids and their role in hydrocarbon migration and oil deposit formation exemplified by supercritical СO2

Published online by Cambridge University Press:  23 March 2021

Sara LIFSHITS Open the ORCID record for Sara LIFSHITS [Opens in a new window]
Sara LIFSHITS*
Affiliation:
Federal Research Center, Yakut Scientific Center, Siberian Branch, Russian Academy of Sciences, Institute of Oil and Gas Problems SB RAS, 20, Avtodorozhnaya Str., Yakutsk, 677007, Russia
*
Email: shlif@ipng.ysn.ru
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Abstract

Hydrocarbon migration mechanism into a reservoir is one of the most controversial in oil and gas geology. The research aimed to study the effect of supercritical carbon dioxide (СО2) on the permeability of sedimentary rocks (carbonates, argillite, oil shale), which was assessed by the yield of chloroform extracts and gas permeability (carbonate, argillite) before and after the treatment of rocks with supercritical СО2. An increase in the permeability of dense potentially oil-source rocks has been noted, which is explained by the dissolution of carbonates to bicarbonates due to the high chemical activity of supercritical СО2 and water dissolved in it. Similarly, in geological processes, the introduction of deep supercritical fluid into sedimentary rocks can increase the permeability and, possibly, the porosity of rocks, which will facilitate the primary migration of hydrocarbons and improve the reservoir properties of the rocks. The considered mechanism of hydrocarbon migration in the flow of deep supercritical fluid makes it possible to revise the time and duration of the formation of gas–oil deposits decreasingly, as well as to explain features in the formation of various sources of hydrocarbons and observed inflow of oil into operating and exhausted wells.

Keywords

chloroform bitumoidformation of oil depositskarst phenomenamigration of hydrocarbonsoil genesisoil shaleoil-source rockspermeability of sedimentary rocks
Type
Articles
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 112 , Issue 1 , March 2021 , pp. 1 - 11
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Copyright
Copyright © The Author(s) 2021. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

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References

6. References

Aliyev, A. A., Abbasov, O. R., Ibadzade, A. J. & Mammadova, A. N. 2018. Genesis and organic geochemical characteristics of oil shale in Eastern Azerbaijan. SOCAR Proceedings Oil and Gas Fields Exploration, Geology and Geophysics 3, 00415.Google Scholar
Balitsky, V. S., Balitskaya, L. V., Bublikova, T. M., Prokof'ev, V. Y. & Pentelei, S. V. 2007. Experimental study of the interaction of mineral-forming hydrothermal solutions with oil and their joint migration. Petrology 3, 211–23.10.1134/S0869591107030010CrossRefGoogle Scholar
Bespalov, A. S., Lermontov, S. A., Sipyagina, N. A., Grashchenkov, D. V. & Buznik, V. M. 2017. Hydrophobization of porous ceramic materials using supercritical fluid technologies. Materials of the All-Russian Scientific and Technical Conference Modern high-temperature fibrous heat and sound insulation materials 2017, 4158. [In Russian.]Google Scholar
Burley, S. D., Clarke, S., Dodds, A., Frielingsdorf, J., Huggins, P., Richards, A., Warburton, I. C. & Williams, G. 2000. New insights on petroleum migration from the application of 4d basin modelling in oil and gas exploration. Journal of Geochemical Exploration 69, 465–70.CrossRefGoogle Scholar
Carruthers, D. & Ringrose, P. 1998. Secondary oil migration: oil-rock contact volumes, flow behaviour and rates. Geological Society London Special Publications 144, 205–20.CrossRefGoogle Scholar
Chepikov, K. R., Yermolova, E. I. & Orlova, N. A. 1959. Epigennyye mineraly kak pokazateli vremeni prikhoda nefti v peschanyye promyshlennyye kollektory [Эпигенные минералы как показатели времени прихода нефти в песчаные промышленные коллекторы]. DAN SSSR, Доклады Академии Наук СССР 5, 1097–99. [In Russian.]Google Scholar
Ezhov, Y. A., Lisenin, G. P., Andreychuk, V. N. & Dublyansky, Y. V. 1992. Karst in the Earth's Crust: distribution and the main types. Academy of Sciences of the Russia, Siberian Division. Associated Institute of Geology, Geophysics and Mineralogy. [In Russian.]Google Scholar
Gavrilov, V. P. 2010. Geodynamic approaches to the problem of oil and gas origin. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdeniy 7, 1522. [In Russian.]Google Scholar
Grecheneva, A. V., Kuzichkin, O. R., Mikhaleva, E. S. & Romanov, R. V. 2017. The results of joint processing of geotechnical and geodynamic monitoring data of karst processes. Journal of Engineering and Applied Sciences 12, 6628–34.Google Scholar
Guliyev, I. S., Kerimov, V. Y., Osipov, A. V. & Mustaev, R. N. 2017. Generation and accumulation of hydrocarbons at great depths under the Earth's crust. SOCAR Proceedings Oil and Gas Fields Exploration, Geology and Geophysics 1, 00416.Google Scholar
Guo, Y., Pang, X., Jiang, Z., Chen, D., Jiang, F. & Dong, Y. 2013. Hydrocarbon generation and migration in the Nanpu Sag, Bohai Bay Basin, Eastern China: insight from basin and petroleum system modeling. Journal of Asian Earth Sciences 77, 140–50.CrossRefGoogle Scholar
Huang, Z., Liang, T., Zhan, Z.-W., Zou, Y.-R., Li, M. & Peng, P. 2018. Chemical structure evolution of kerogen during oil generation. Marine and Petroleum Geology 98, 422436. DOI: 10.1016/j.marpetgeo.2018.08.03910.1016/j.marpetgeo.2018.08.039CrossRefGoogle Scholar
Ivannikov, V. I. 2010. The nature of abnormal layer pressures in oil and gas collectors and its significance for hydrocarbon accumulations prospecting. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdeniy, Геология, геофизика и разработка нефтяных и газовых месторождений 3, 3639. [In Russian.]Google Scholar
Jiao, W., Yang, H., Zhao, Y., Zhang, H., Zhou, Y., Zhang, J. & Xie, Q. 2010. Application of trace elements in the study of oil-source correlation and hydrocarbon migration in the Tarim Basin, China. Energy Exploration and Exploitation 28, 451–66.10.1260/0144-5987.28.6.451CrossRefGoogle Scholar
Kayukova, G. P., Mikhailov, A. N., Kosachev, I. P., Morozov, V. P. & Vakhin, A. V. 2020. Hydrothermal transformations of organic matter of carbon-rich domanik rock in carbon dioxide. Environment at different temperatures. Petroleum Chemistry 60, 278–90.10.1134/S0965544120030093CrossRefGoogle Scholar
Khasanov, R., Mullakaev, A., Galiullin, B. & Khayrtdinova, L. 2017. The influence of hydrothermal processes in the crystalline basement on the oil-bearing capacity of the sedimentary cover of the Volga-Ural region (Russia). 17th International multidisciplinary scientific geoconference SGEM, Albena, Bulgaria, 2017. Conference proceedings, 631–36.Google Scholar
Khromykh, L. N., Litvin, A. T. & Nikitin, A.V. 2018. Application of carbon dioxide in enhanced oil recovery. The Eurasian Scientific Journal 5(10). https://esj.today/PDF/06NZVN518.pdf. [In Russian.]Google Scholar
Letnikov, F. A. 2016. Thermodynamic analysis of endogeneous fluid systems: the paradigm shift of the 21st century. Doklady Earth Sciences 468, 584–86.10.1134/S1028334X16060192CrossRefGoogle Scholar
Lifshits, S. H. & Chalaya, O. N. 2010. Possible mechanism of oil formation in a flow of supercritical fluid (using carbon dioxide as an example). Russian Journal of Physical Chemistry B 7, 1142–48.10.1134/S1990793110070146CrossRefGoogle Scholar
Lifshits, S. K. 2009. The principle of oil formation in the supercritical flow of deep fluids. Herald of the Russian Academy of Sciences 79, 174–48.10.1134/S1019331609020142CrossRefGoogle Scholar
Lifshits, S. K., Chalaya, O. N. & Zueva, I. N. 2012. Extraction of hydrocarbons from carbonaceous rock in supercritical carbon dioxide. Journal of Physical Chemistry B 6, 15.Google Scholar
Liu, Q. Q., Han, X. X., Li, Q. Y., Huang, Y. R. & Jiang, X. M. 2014. TG–DSC analysis of pyrolysis process of two Chinese oil shales. Journal of Thermal Analysis and Calorimetry 116, 511–17.CrossRefGoogle Scholar
Lukin, A. Y. & Pikovsky, Y. I. 2004. About role of deep and superdeep fluids in the processes of oil and gas formation. Geologichnij zhurnal, Геологiчний журнал 2, 2133. [In Russian.]Google Scholar
Luo, X., Jin, Z., Liu, K. & Zhang, S. 2017. Geofluids in deep sedimentary basins and their significance for petroleum accumulation. Geofluids, Article ID 3571359: 4. https://doi.org/10.1155/2017/3571359.CrossRefGoogle Scholar
Makaryan, I. A., Kostin, A. Y. & Sedov, I. V. 2020. Application of supercritical fluid technologies in chemical and petrochemical industries (review). Petroleum Chemistry 60, 244–54.10.1134/S0965544120030135CrossRefGoogle Scholar
Measurement technique. Determination of the group composition of chloroform bitumoids of rock, soils and stripped oils by the gravimetric method. 2014. No. 222.0119/01.00258 / 2014. 15 p. from 08.05.2014. Yakutsk, Russia: Institut problem nefti i gaza Sibirskogo otdeleniya Rossiyskoy akademii nauk. http://ipng.ysn.ru/wp-content/uploads/2020/04/hms-scaled.jpg [In Russian]Google Scholar
Muslimov, R. K. & Plotnikova, I. N. 2019. Replenishment of oil deposits from the position of a new concept of oil and gas formation. Georesources 21, 4048.CrossRefGoogle Scholar
Prigogine, I. 1961. Introduction to thermodynamics of irreversible processеs. 2nd edn. New York: Interscience.Google Scholar
Qu, X.-Y., Liu, L., Yang, H.-D., Liu, N., Zhang, L.-D. & Wang, W.-X. 2011. Genesis of oil-associated CO2 and its significance in petroleum geology. Journal of China University of Petroleum (Edition of Natural Science) 35, 4146.Google Scholar
Rachinsky, M. Z. & Kerimov, V. U. 2015. Fluid dynamics of oil and gas reservoirs. Hoboken, New Jersey, USA: Scrivener Publishing Wiley, 2015, 613. doi: 10.1002/9781118999004CrossRefGoogle Scholar
Rzoska, S. J. & Rzoska, A. D. 2010. New proposals for supercritical fluids applications. In Rzoska, S., Drozd-Rzoska, A. & Mazur, V. (eds) Metastable systems under pressure. NATO science for peace and security series A: chemistry and biology. Dordrecht: Springer, 167179.Google Scholar
Scalera, G. 2012. Biogenic/abiogenic hydrocarbons origin -- possible role of tectonically active belts. The Earth Expansion Evidence – A Challenge for Geology, Geophysics and Astronomy Selected Contributions to the Interdisciplinary Workshop of the 37th International School of Geophysics EMFCSC, Erice, Italy (4–9 October 2011), 463–75.Google Scholar
Serovaiskii, A. Y. & Kutcherov, V. G. 2020. Formation of complex hydrocarbon systems from methane at the upper mantle thermobaric conditions. Scientific Reports 10, 225–26.10.1038/s41598-020-61644-5CrossRefGoogle Scholar
Skvortsov, V. A. 2019. The sedimentary–migration–igneous hypothesis of oil formation. Doklady Earth Sciences 486, 692–94.10.1134/S1028334X19060229CrossRefGoogle Scholar
Teng, J.-W., Liu, Y.-S. & Qiao, Y.-H. 2017. Study and exploration of the mixed-origin theories of organic and inorganic oil and gas. Chinese Journal of Geophysics 60, 1874–92.Google Scholar
Timurziev, A. I. 2009. Contemporary state of hypothesis of oil sedimentary-migration origin. Geologiya, geofizika i razrabotka neftyanyh i gazovyh mestorozhdenij 12, 3038. Leningrad: Nedra. [In Russian.]Google Scholar
Tissot, B. P. 1984. Petroleum formation and occurrence. New York: Springer-Verlag.10.1007/978-3-642-87813-8CrossRefGoogle Scholar
Uspenskiy, V. A. 1975. Metody bituminologicheskikh issledovaniy. Zadachi issledovaniy i puti ikh razrabotki. [In Russian.]Google Scholar
Vu, V. H., Serebrennikova, O. V. & Savinykh, Y. V. 2012. Сomposition and sources of oils in the terrigenous and volcanogenic reservoirs from white tiger deposit (Vietnam). Vestnik Tomskogo gosudarstvennogo universiteta, Вестник Томского государственного университета 361, 165–70. [In Russian.]Google Scholar
Wang, T., Zhang, D.-L., Yang, X.-Y., Xu, J.-O., Matthew, C. & Tang, Y.-J. 2020. Light hydrocarbon geochemistry: insight into oils/condensates families and inferred source rocks of the Woodford–Mississippian tight oil play in north-central Oklahoma, USA. Petroleum Science 17, 582–97.CrossRefGoogle Scholar
Zhang, J., Cao, J., Wang, Y., Li, J., Hu, G., Zhou, N. & Shi, T. 2019. Geochemistry and genesis of oil and gas seeps in the Junggar Basin, NW China: implications for hybrid petroleum systems. Geofluids, 126.Google Scholar
Zhu, D., Liu, Q., Jin, Z., Meng, Q. & Wenxuan, H. U. 2017. Effects of deep fluids on hydrocarbon generation and accumulation in Chinese petroliferous basins. Acta Geologica Sinica (English Edition) 91, 301–19.10.1111/1755-6724.13079CrossRefGoogle Scholar