Using the approach of step-by-step lithological dissection of the section of volcanogenic sedimentary deposits

The article implements an approach of step-by-step lithological dissection of the section of volcanogenic sedimentary rocks of the Sredne-Nazymskoye field using comparisons of methods of geophysical surveys of rocks at the qualitative and quantitative level.
The predominantly acidic composition of the rocks determines the use of unified petrophysical algorithms for the section of the Pre-Jurassic complex with additional division into enlarged groups of lithotypes: lavobreccia, tuffs and unchanged effusions. An important factor influencing the interpretation of geophysical surveys is the presence of rock fracturing in the Pre-Jurassic complex interval.
The assessment of the possibility of lithological dissection of the section, taking into account the additional division of rocks into collector-non-collector, which allows us to identify promising zones of development of pore and fractured reservoirs.
We propose an approach of step-by-step lithological dissection of the section, including qualitative and quantitative criteria, which ensures the improvement of existing technologies.

1. Kos, I. M., Belkin, N. M., & Kuryshevа, N. K. (2004). Seysmogeologicheskoe stroenie doyurskikh obrazovaniy Rogozhnikovskogo mestorozhdeniya. Russian Geophysics, (S), pp. 77-82. (In Russian).

2. Voron, I. A. (2017). Geologicheskoe stroenie Sredne-Nazymskogo mestorozhdeniya i proekt dorazvedki zalezhey nefti v doyurskikh otlozheniyakh. Aktual'nye voprosy poiskov i razvedki mestorozhdeniy nefti i gaza: sbornik nauchnykh trudov konferentsii. Moscow, September, 28-29, 2017. Moscow, Neft' i gaz Publ., pp. 168-173. (In Russian).

3. Popov, I. P. & Kuzmin, A. Yu. (2016). Obosnovanie kompleksa issledovaniy treshchinnykh kollektorov plasta TR Rogozhnikovskogo mestorozhdeniya. Estestvennye i tekhnicheskie nauki, (4(94)), pp. 54-57. (In Russian).

4. Seyidov, Vagif oglu Mirgaza. (2019). Оn the determination of petrophysical parameters of effusive collectors based on industrial and geophysical data. Education and science in Russia and abroad, (3(51)), рр. 425-435. (In Russian).

5. Gilmanova, N. V. (2007). Razrabotka metodov litologicheskogo raschleneniya i mezhskvazhinnoy korrelyatsii geologicheskikh razrezov terrigennykh i vulkanogenno-osadochnykh otlozheniy na osnove dannykh issledovaniy skvazhin. Аvtoref. diss. … kand. geol.-mineral. nauk. Tyumen, 15 p. (In Russian).

6. Bergal-Kuvikas, O. V., Churikova, T. G., Gordeychik, B. N., Ladygin, V. M., Kronz, A., & Wörner, G. (2020). Physical and chemical variations of volcanic rocks from historical eruptions of Klyuchevskoy volcano, Kamchatka. Abstracts of XII L. L. Perchuk International School of Earth Sciences (Ises-2020). Available at: https://www.elibrary.ru/item.asp?id=44364433

7. Yh, H. M., Zhao, B., Xu, J. D., & Wei, F. X. (2017). Magmatic processes of Daheishan volcano, Ashikule volcano cluster in the western Kunlun Mountains, China. Acta petrologica sinica, 33(1), pp. 56-58. (In Chinese).

8. Glebocheva, N. K., Telenkov, V. M., & Khamatdinova, E. R. (2009). The structure of the capacitive space of effusive reservoirs according to logging and core data. Karotazhnik, (6(183)), pp. 3-10. (In Russian).

9. Yumatov, A. Yu. Rasprostranenie uprugikh prodol'nykh voln v poristykh gornykh porodakh s treshchinami i kavernami. Diss. … kand. fiz.-mat. nauk. Moscow, 133 р. (In Russian).

10. Rowell, C. R., Fee, D., Szuberla, C. A. L., Arnoult, K., Matoza, R. S., Firstov, P. P.,… Kim, K. (2014). Three-dimensional volcano-acoustic source localization at Karymsky volcano, Kamchatka, Russia. Journal of volcanology and geothermal research, 283, pp. 101-115. (In English). DOI: 10.1016/j.jvolgeores.2014.06.015

11. Efimov, V. A. (2006). The nuclear physics characteristic of volcanogenic rocks. Oil Industry, (8), рр. 108-110. (In Russian).

12. Khamatdinova, E. R. (2008). Filtration and capacity properties of west Siberian effusive reservoirs. Karotazhnik, 12(177), рр. 19-32. (In Russian).

13. Plotnikov, V. V. & Terentiev, B. V. (2007). Vliyanie treshchinovatosti na petrofizicheskie svoystva porodkollektorov. Geology, Geophysics and Development of Oil and Gas Fields, (9), pp. 10-13. (In Russian).

14. Dobrynin, V. M. Vendelstein, B. Yu. & Kozhevnikov, D. A. (2004). Petrofizika (fizika gornykh porod). Moscow, Neft' i gaz Publ., 368 p. (In Russian).

15. Tiab, D., & Donalson, E. C. (2003). Petriphysics. Theory and practice of measuring reservoir rock and fluid transport properties. Amsterdam [etc.], Elsevier, 864 p. (In English).

16. Nechai, A. M. (1954). Opredelenie litologicheskikh svoystv gornykh porod po rezul'tatam geofizicheskikh issledovaniy v skvazhinakh. Prikladnaya geofizika, (11), pp. 3-49. (In Russian).

17. Boyarchuk, A. F. (1983). Sovremennoe sostoyanie i perspektivy razvitiya promyslovo-geofizicheskikh metodov izucheniya treshchinnykh kollektorov. Moscow, VNIIONG, Publ., 57 p. (In Russian).

18. Knyazev, A. R. (2009). Otsenka treshchinovatosti nizkoporistykh karbonatnykh porod po rezul'tatam geofizicheskikh issledovaniy skvazhin. Avtoref. diss. … kand. geol.-mineral. nauk. Perm, 26 p. (In Russian).

19. Khotylev, A. O. (2019). Stroenie doyurskogo kompleksa Krasnoleninskogo svoda (Zapadnaya Sibir'): sostav, struktura i neftenosnost'. Geologiya, geoekologiya i resursnyy potentsial Urala i sopredel'nykh territoriy, (7), рр. 32-36. (In Russian).

20. Guziyev, I. S., & Vlasov, V. V. (1980). Factors in Regional Authigenic Zeolitization of Ash Tuffs. International Geology Review, 22(12), pp. 1421-1433. (In English).

21. Zinchuk, N. N., Kotel'nikov, D. D., & Sokolov, V. N. (1983). Weathering alteration of tuffs and tuffogenic rocks in Yakutia. International Geology Review, 25(12), pp. 1425-1435. (In English). DOI: 10.1080/00206818309466849