Shumskayte M.Y.

ShumskaiteMI@ipgg.sbras.ru

Graduated from Ural Federal University (2012), specialization "atomic nucleus and elementary particle physics".
PhD in Technical Sciences.
Senior Researcher of Trofimuk Institute of Petroleum Geology and Geophysics of Siberian Branch Russian Academy of Sciences (IPGG SB RAS).
Area of scientific interests: nuclear magnetic resonance, petrophysics, filtration and capacity properties of rocks, rheological properties of hydrocarbons, phase states, gas hydrates..
Author of 18 publications.

Stratigraphy and lithology

Article # 8_2025	submitted on 11/12/2024 displayed on website on 02/24/2025
19 p.	Shumskayte M.Y., Yanushenko T.A., Golikov N.A.
pdf	Study of permafrost rocks of the Bykov peninsula by laboratory methods of dielectric spectroscopy and nuclear magnetic resonance
	The complex permittivity of sedimentary rocks mainly depends on the porosity and water saturation. For frozen rocks, the complex permittivity is also determined by the state of water in the pores. This is due to the difference in permittivity and electrical conductivity of free water and ice in the pores of the rock. In fine-porous rocks, the influence of bound water is great, the properties of which differ from the properties of free water. A study of the granulometric composition and specific electrical resistance of rocks was carried out on samples of permafrost rocks, and measurements were also made using the nuclear magnetic resonance method. Nuclear magnetic resonance is widely used in geological and geophysical studies to determine the filtration-capacitive properties of rocks and the rheological properties of formation fluids. It was found that the transformation of water into ice with a decrease in temperature does not occur at a certain temperature, but in a certain range of negative temperatures. It was found that the dielectric constant changes by approximately 6 for different wells. According to NMR data, a connection was established between water saturation and granulometric composition and the dependence of the transverse relaxation time on the degree of mineralization and temperature of rocks. Keywords: complex permittivity, NMR relaxometry, permafrost rock, Bykov peninsula.
article citation	Shumskayte M.Y., Yanushenko T.A. Golikov N.A. Izuchenie mnogoletnemerzlykh porod Bykovskogo poluostrova laboratornymi metodami dielektricheskoy spektroskopii i yadernogo magnitnogo rezonansa [Study of permafrost rocks of the Bykov peninsula by laboratory methods of dielectric spectroscopy and nuclear magnetic resonance]. Neftegazovaya Geologiya. Teoriya I Praktika, 2025, vol. 20, no. 1, available at: https://www.ngtp.ru/rub/2025/8_2025.html EDN: OORYLZ

References

   Bittar M.S., Li J. High frequency dielectric measurement tool: patent 20110221443 USA, G01V 3/10; applicant and patentee Halliburton Energy Services, Inc, No 13128676; application date 11.08.2009; publication date 15.09.2011.
   Comparon L., Hizem M. System and method to measure dielectric constant in a subterranean well: patent 12669195 USA, G01V 3/00, G01V 3/10; applicant and patentee Schlumberger Technology Corporation, No 12669195; application date 09.06.2008; publication date 11.11.2010.
   Dzhafarov I.S., Syngaevskiy P.E., Khafizov S.F. Primenenie metoda yadernogo magnitnogo rezonansa dlya kharakteristiki svoystva i raspredeleniya plastovykh flyuidov [Nuclear magnetic resonance application for reservoir fluids distribution and properties characterization]. Moscow: Khimiya, 2002, 439 p. (In Russ.).
   Epov M.I., Savin I.V., Mironov V.L. Dielektricheskaya temperaturnaya model' vlazhnykh neftesoderzhashchikh porod v diapazone chastot ot 0,5 do 15 GGts [Dielectric temperature model of wet oil-bearing rocks in the frequency range from 0.5 to 15 GHz]. Geologiya i geofizika, 2012, no. 7, pp. 912-919. (In Russ.). DOI: 10.1016/j.rgg.2012.05.008
   Fleury M., Deflandre F., Godefroy S. Validity of permeability prediction from NMR measurements. Comptes Rendus de l'Académie des Sciences, Chemistry, 2001, no. 4, pp. 869-872. DOI: 10.1016/S1387-1609(01)01343-3
   Freedman R., Heaton N. Fluid characterization using nuclear magnetic resonance logging. Petrophysics, 2004, no. 45, pp. 241-250.
   Freedman R., Heaton N., Flaum M., Hirasaki G, Flaum C, Hurlimann M. Wettability saturation and viscosity from NMR measurements. SPE Journal, 2003, no. 8, pp. 317-327. DOI: 10.2118/87340-PA
   Repin A.V., Bobrov P.P., Golikov N.A. Dielectricheskaya pronicaemost’ neftevodonasyshchennykh kernov bazhenovskoy svity [Dielectric constant of oil-saturated cores of the Bazhenov Formation]. Aktualnye problemy geologii nefti I gaza Sibiri: materialy Vserossiyskoy nauchnoy konferencii molodykh uchenykh I studentov, posvyashch. 80-letiyu akad. A.E. Kontorovicha (Novosibirsk, 10-15 Feb 2014). INGG SO RAN: Novosibirsk, 2014, pp. 228-231. (In Russ.).
   Shumskayte M., Junasheva A., Eltsov T., Golikov N. Electrophysical parameters and NMR-characteristics of cryogel. IOP Conference Series: Earth and Environment Science, 2016, vol. 43, Paper 012021, 7 p. DOI: 10.1088/1755-1315/43/1/012021
   Shumskayte M.Y., Glinskikh V.N. Analiz vliyaniya ob"emnogo soderzhaniya i tipa glinistykh mineralov na relaksatsionnye kharakteristiki peschano-alevritovykh obraztsov kerna [Analysis of the effect of volumetric content and the type of clay minerals on relaxation characteristics of sandy-aleuritic core samples]. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdeniy, 2015, no. 7, pp. 35-38 (In Russ.). EDN: UAPYRX
   Shumskayte M.Y., Glinskikh V.N. Eksperimental'noe issledovanie zavisimosti YAMR-kharakteristik ot udel'noy poverkhnosti i udel'nogo elektricheskogo soprotivleniya peschano-alevritoglinistykh obraztsov [Relation of NMR parameters with specific surface and resistivity of shaly sandstone and siltstone samples: experimental study]. Geologiya i geofizika, 2016, vol. 57, no. 10, pp. 1911-1918. (In Russ.). DOI: 10.15372/GiG20161009
   Sudakova M.S., Vladov M.L. Experimentalnoe issledovanie akusticheskikh svoystv vodonasyshchennogo peska v interval temperatury ot –20 до +20ᵒС [Experimental study of the acoustic properties of water-saturated sand in the temperature range from –20 до +20ᵒС]. Vestnik Moskovskogo universiteta. Seriya 4. Geologiya, 2019, no. 4, pp. 55-62. (In Russ.). DOI: 10.33623/0579-9406-2019-4-55-62
Tabarin V.A., Dem’yanceva S.D. Opredelenie soderzhaniya svyazannoy vody v kernakh na SVCh [Determination of bound water content in cores using microwave]. Neftegazovoe delo, 2009, vol. 7, no. 1, pp. 1-28. (In Russ.).

Geochemical research

Article # 41_2024	submitted on 10/28/2024 displayed on website on 12/23/2024
17 p.	Shumskayte M.Y., Fomin M.A., Saitov R.M., Yanushenko T.A., Gorshkov A.M.
pdf	Application the NMR relaxometry method to study the structure of the void space of different rocks and determining the properties of the saturating fluid
	Nuclear magnetic resonance is widely-accepted method in geological and geophysical studies to determine the filtration and capacitance properties of rocks and the rheological properties of formation fluids. To study the structure of the rocks pore space, the work explores the possibility of using two-dimensional maps of longitudinal and transverse relaxation times. The nuclear magnetic resonance characteristics of core samples and fluids of different compositions were studied and the distribution of nuclear magnetic resonance relaxation times was analyzed. It has been established that in the case of two-phase saturation, a joint analysis of both longitudinal and transverse relaxation times makes it possible to determine with a high degree of reliability the type of fluid and its position in the pore space of the sample. For rock samples of the Bazhenov Formation, it was shown that during the extraction process, the internal structure of high-carbon samples is destroyed, followed by the redistribution of hydrocarbon fluids in the void space of the rock. Keywords: NMR relaxometry, two-dimensional maps of relaxation time, fluid saturation, Bazhenov Formation.
article citation	Shumskayte M.Y., Fomin M.A., Saitov R.M., Yanushenko T.A., Gorshkov A.M. Ispol'zovanie yadernogo magnitnogo rezonansa - relaksometrii dlya izucheniya struktury pustotnogo prostranstva razlichnykh po sostavu porod i opredeleniya svoystv nasyshchayushchego flyuida [Application the NMR relaxometry method to study the structure of the void space of different rocks and determining the properties of the saturating fluid]. Neftegazovaya Geologiya. Teoriya I Praktika, 2024, vol. 19, no. 4, available at: https://www.ngtp.ru/rub/2024/41_2024.html EDN: HYZPOG

References

   Fleury M, Deflandre F, Godefroy S. Validity of permeability prediction from NMR measurements. Comptes Rendus de l'Académie des Sciences, Chemistry, 2001, no 4, pp. 869-872. DOI: 10.1016/S1387-1609(01)01343-3
   Freedman R., Heaton N. Fluid characterization using nuclear magnetic resonance logging. Petrophysics, 2004, no. 45, pp. 241-250.
   Freedman R., Heaton N., Flaum M., Hirasaki G., Flaum C., Hurlimann M. Wettability saturation and viscosity from NMR measurements. SPE Journal, 2003, no. 8, pp. 317-327. DOI: 10.2118/87340-PA
   Gorshkov A.M., Saitov R.M. Metodika opredeleniya poristosti i nasyshchennosti slancevykh porod na dezintegrirovannom kerne [Methodology for determining porosity and saturation of shale rocks on disintegrated core]. Neftyanoe khozyaystvo, 2023, no. 1, pp. 6-12. (In Russ.). DOI: 10.24887/0028-2448-2023-1-6-12
   Hursan G., Seifert D.J., Lyngra S., Palmer R.G. Oil viscosity estimation from NMR logs for in-situ heavy oil characterization. SPE Annual Technical Conference and Exhibition (26-28 Sept 2016, Dubai, UAE), 2016, paper 181600-MS, 13 p. DOI: 10.2118/181600-MS
   Kausik R., Fellah K., Feng L., Freed D., Simpson G. High- and Low-Field NMR Relaxometry and Diffusometry of the Bakken Petroleum System. SPWLA 57th Annual Logging Symposium (25-29 June 2016, Reykjavik, Iceland), 2016, Paper SSS, 7 p.
   Kontorovich A.E., Rodyakin S.V., Burshteyn L.M., Kostyreva E.A., Ryzhkova S.V., Yan P.A. Poristost’ i neftenasyshchennost’ porod bazhenovskoy svity [Porosity and oil saturation of Bazhenov Formation rocks]. Geologiya nefti i gaza, 2018, no. 5, pp. 61-73. (In Russ.). DOI: 10.31087/0016-7894-2018-5-61-73
   Kontorovich A.E., Yan P.A., Zamiraylova A.G., Kostyreva E.A., Eder V.G. Klassifikasiya porod bazhenovskoy svity [Classification of Bazhenov Formation rocks]. Geologiya i geofizika, 2016, no. 11, pp. 2034-2043. (In Russ.). DOI: 10.15372/GiG20161106
   Korb J.P., Vorapalawut N., Nicot B., Bryant R.G. Relation and Correlation between NMR Relaxation Times, Diffusion Coefficients, and Viscosity of Heavy Crude Oils. The Journal of Physical Chemistry, 2015, vol. 119, no. 43, pp. 24439-24446. DOI: 10.1021/acs.jpcc.5b07510
   Primenenie metoda yadernogo magnitnogo rezonansa dlya kharakteristiki svoystva i raspredeleniya plastovykh flyuidov [Nuclear magnetic resonance application for reservoir fluids distribution and properties characterization]. I.S. Dzhafarov, P.E. Syngaevskiy, S.F. Khafizov. Moscow: Khimiya, 2002, 439 p. (In Russ.).
   Shumskayte M.Y., Glinskikh V.N. Analiz vliyaniya ob"emnogo soderzhaniya i tipa glinistykh mineralov na relaksatsionnye kharakteristiki peschano-alevritovykh obraztsov kerna [Analysis of the effect of volumetric content and the type of clay minerals on relaxation characteristics of sandy-aleuritic core samples]. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdeniy, 2015, no. 7, pp. 35-38. (In Russ.).
   Shumskayte M.Y., Glinskikh V.N. Eksperimental'noe issledovanie zavisimosti YAMR-kharakteristik ot udel'noy poverkhnosti i udel'nogo elektricheskogo soprotivleniya peschano-alevritoglinistykh obraztsov [Relation of NMR parameters with specific surface and resistivity of shaly sandstone and siltstone samples: experimental study]. Geologiya i geofizika, 2016, vol. 57, no. 10, pp. 1911-1918. (In Russ.). DOI: 10.15372/GiG20161009
   Shumskayte M.Y., Glinskikh V.N., Bortnikova S.B., Kharitonov A.N., Permyakov V.S. Laboratornoe izuchenie zhidkostey vynosimykh iz skvazhin metodom YAMR-relaksometrii [NMR-relaxometry laboratory study of fluids taken from boreholes]. Izvestiya Tomskogo politekhnicheskogo universiteta.Inzhiniring georesursov, 2017, vol. 328, no. 2, pp. 59-66. (In Russ.).
   Zaripov T.A., Doroginitskiy M.M., Gizatullin B.I., Abdullin T.R., Musin K.M., Murzakaev V.M. Rezul'taty izucheniya vyazkosti nefti s mestorozhdeniy respubliki Tatarstan s pomoshch'yu metoda Yadernoy magnitno-rezonansnoy relaksometrii [Results of oil viscosity study from Tatarstan fields through nuclear magnetic resonance relaxometry]. Karotazhnik, 2015, no. 253, pp. 3-13. (In Russ.).

Geochemical research

Section editor – PhD in geology and mineralogy Bazhenova T.K.

Article # 29_2017	submitted on 06/14/2017 displayed on website on 09/04/2017
15 p.	Turakhanov A.K., Glinskikh V.N., Kashirtsev V.A., Fursenko E.A., Shumskayte M.Y.
pdf	The application of the Nuclear Magnetic Resonance Relaxometry method to express-study of rheological properties and composition of oil and gas condensate
	Nuclear Magnetic Resonance is widely used today in laboratory and borehole studies of rock porosity and permeability properties. Applying to oil-containing fluid physicochemical properties investigation this paper is devoted to Nuclear Magnetic Resonance Relaxometry possibilities study as an express-method of rheological properties evaluation and saturates, aromatics, resins and asphaltenes (SARA) analysis of hydrocarbons samples. Nuclear Magnetic Resonance Relaxometry properties of hydrocarbons samples from a number of fields in Western Siberia were studied. A comparative analysis with the results of standard geochemical studies was made. Keywords: Nuclear Magnetic Resonance Relaxometry, rheological properties oil and gas condensate, SARA analysis of hydrocarbons.
article citation	Turakhanov A.K., Glinskikh V.N., Kashirtsev V.A., Fursenko E.A., Shumskayte M.Y. Primenenie yadernogo magnitnogo rezonansa - relaksometrii dlya ekspress-issledovaniya reologicheskikh svoystv i gruppovogo sostava nefti i kondensata [The application of the Nuclear Magnetic Resonance Relaxometry method to express-study of rheological properties and composition of oil and gas condensate]. Neftegazovaya Geologiya. Teoriya I Praktika, 2017, vol. 12, no. 3, available at: http://www.ngtp.ru/rub/1/29_2017.pdf
DOI	https://doi.org/10.17353/2070-5379/29_2017

References

   Dzhafarov I.S., Syngaevskiy P.E., Khafizov S.F. Primenenie metoda yadernogo magnitnogo rezonansa dlya kharakteristiki svoystva i raspredeleniya plastovykh flyuidov [The application of the nuclear magnetic resonance method to characterize the feature and distribution of formation fluids]. Moscow, Khimiya, 2002, 439 p.
   Fleury M., Deflandre F., Godefroy S. Validity of permeability prediction from NMR measurements. Comptes Rendus de l'Academie des Sciences, Chemistry, 2001, no. 4, p. 869-872.
   Freedman R, Heaton N. Fluid characterization using nuclear magnetic resonance logging. Petrophysics, 2004, no. 45, p. 241-250.
   Freedman R., Heaton N., Flaum M., Hirasaki G., Flaum C., Hurlimann M. Wettability saturation and viscosity from NMR measurements. SPE Journal, 2003, no. 8, p. 317–327. DOI: https://doi.org/10.2118/87340-PA
   GOST R 51858-2002. Neft'. Obshchie tekhnicheskie usloviya [Oil. General technical requirements]. Moscow, GOSSTANDART ROSSII, 2002, 11 p.
   Hursan G., Seifert D.J., Lyngra S., Palmer R.G. Oil viscosity estimation from NMR logs for in-situ heavy oil characterization. SPE Annual Technical Conference and Exhibition, 26-28 September, Dubai, UAE, 2016, Paper 181600-MS, 13 p. DOI: https://doi.org/10.2118/181600-MS
   Jones M., Taylor S.E. NMR Relaxometry and Diffusometry in characterizing structural, interfacial and colloidal properties of heavy oils and oil sands. Advances in Colloid and Interface Science, 2015, no. 224, p. 33-45. DOI: https://doi.org/10.1016/j.cis.2015.07.007
   Kausik R., Fellah K., Feng L., Freed D., Simpson G. High- and Low-Field NMR Relaxometry and Diffusometry of the Bakken Petroleum System. SPWLA 57th Annual Logging Symposium, 25-29 June, Reykjavik, Iceland, 2016, Paper SSS, 7 p.
   Korb J.P., Vorapalawut N., Nicot B., Bryant R.G. Relation and Correlation between NMR Relaxation Times, Diffusion Coefficients, and Viscosity of Heavy Crude Oils. The Journal of Physical Chemistry, 2015, vol. 119, no. 43, p. 24439-24446. DOI: https://doi.org/10.1021/acs.jpcc.5b07510
   Mirotchnik K, Kantzas A, Starosud A, Aikman M. A New method for group analysis of petroleumfractions in unconsolidated porous media. Journal of Canadian Petroleum Technology, 2001, no. 40, p. 38-44.
   Perepuhov A.M., Shestakov S.L. Algoritm obratnogo preobrazovaniya Laplasa dlya obrabotki slozhnyh relaksatsionnyh zavisimostey [Inverse Laplace transformation algorithm for complex relaxation dependencies processing]. Trudy MFTI, 2010, vol. 2, no 2, p. 35–40.
   Shkalikov N.V., Skirda V.D., Arсhipov R.V. Solid-like component in the spin-spin NMR-relaxation of heavy oils. Magnetic Resonance in Solids. Electronic Journal, 2006, vol. 8, no. 1, p. 38-42.
   Shumskayte M.Y., Dolomanskiy Yu.K. Otsenka obemnogo soderzhaniya i tipa glinistykh mineralov s ispolzovaniem YAMR-relaksometrii [Evaluation of the volume content and clay minerals type using NMR relaxometry]. Tyumen-2013: Novye geotekhnologii dlya starykh provintsiy: materialy 3-y mezhdunarodnoy nauchno-prakticheskoy konferentsii. Tyumen, 2013. CD-ROM, PR3. – 10.3997/2214-4609.20142726. Rezhim dostupa: http://www.earthdoc.org/publication/publicationdetails/?publication=67252.
   Shumskayte M.Y., Glinskikh V.N. Analiz vliyaniya ob"emnogo soderzhaniya i tipa glinistykh mineralov na relaksatsionnye kharakteristiki peschano-alevritovykh obraztsov kerna [Analysis of the effect of volumetric content and the clay minerals type on relaxation characteristics of sandy-aleuritic core samples]. Geologiya, geofizika i razrabotka neftyanykh i gazovykh mestorozhdeniy, 2015, no 7, p. 35-38.
   Shumskayte M.Y., Glinskikh V.N. Eksperimental'noe issledovanie zavisimosti YAMR-kharakteristik ot udel'noy poverkhnosti i udel'nogo elektricheskogo soprotivleniya peschano-alevritoglinistykh obraztsov [Relation of NMR parameters with specific surface and resistivity of shaly sandstone and siltstone samples: experimental study]. Geologiya i geofizika, 2016, vol. 57, no 10, p. 1911-1918.
   Shumskayte M.Y., Glinskikh V.N. Izuchenie udelnoy poverkhnosti vodonasyshchennykh peschano-alevrolitovykh porod po dannym YAMR-relaksometrii [Specific surface area study of sand-siltstone rocks using NMR-relaxometry]. Tyumen-2015: Glubokie gorizonty nauki i nedr: Materialy 4-y mezhdunarodnoy nauchno-prakticheskoy konferentsii. Tyumen, 2015. CD-ROM, PP02. – 10.3997/2214-4609.201412051. Rezhim dostupa: http://www.earthdoc.org/publication/publicationdetails/?publication=79691.
   Shumskayte M.Y., Glinskikh V.N., Bortnikova S.B., Kharitonov A.N., Permyakov V.S. Laboratornoe izuchenie zhidkostey vynosimykh iz skvazhin metodom YAMR-relaksometrii [NMR-relaxometry laboratory study of fluids taken from boreholes]. Izvestiya Tomskogo politekhnicheskogo universiteta. Inzhiniring georesursov, 2017, vol. 328, no 2, p. 59-66
   Turakhanov A.K., Glinskikh V.N., Fursenko E.A., Shumskayte M.Y. Ekspressnoe izuchenie gruppovogo sostava i reologicheskikh svoystv uglevodorodov metodom YAMR-relaksometrii [Express-study of SARA analysis and rheological properties of hydrocarbons using NMR-relaxometry]. Tyumen-2017: Geonauki – klyuch k ratsionalnomu osvoeniyu nedr: materialy 5-y mezhdunarodnoy nauchno-prakticheskoy konferentsii. Tyumen, 2017. CD-ROM, C03. –10.3997/2214-4609.201700082. Rezhim dostupa: http://www.earthdoc.org/publication/publicationdetails/?publication=87663.
   Zaripov T.A., Doroginitskiy M.M., Gizatullin B.I., Abdullin T.R., Musin K.M., Murzakaev V.M. Rezul'taty izucheniya vyazkosti nefti s mestorozhdeniy respubliki Tatarstan s pomoshch'yu metoda Yadernoy magnitno-rezonansnoy relaksometrii [Results of oil viscosity study from Tatarstan fields employing nuclear magnetic resonance relaxometry]. Karotazhnik, 2015, no. 253, p. 3-13.