Краткий обзор современных российских исследований в 2015-2020 гг


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International Journal of Applied and Fundamental Research [Meždunarodnyj žurnal prikladnyh i fundamental'nyh issledovanij]. 2019; 12(1): 151–156. (In Russian)

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  2. Em Y, Stoporev A, Semenov A, Glotov A, Smirnova E, Villevald G, et al. Methane hydrate formation in halloysite clay nanotubes. ACS Sustainable Chem. Eng. 2020; 8(21): 7860–7868.

  3. Yakushev VS, Semenov AP, Bogoyavlensky VI, et al. Experimental modeling of methane release from intrapermafrost relic gas hydrates when sediment temperature change. Cold Reg. Sci. Technol. 2018; 149: 46–50.

  4. Chuvilin EM, Grebenkin SI. Experimental estimation of gas permeability of gas-saturated sediments during hydrate formation and freezing. Earth's Cryosphere [Kriosfera zemli]. 2015; 19(2): 59–64.

  5. Chuvilin EM, Davletshina DA, Lupachik MV. Hydrate formation in frozen and thawing methane-saturated sediments. Earth's Cryosphere. 2019; 23(2): 44–52.

  6. Manakov AYu, Penkov NV, Rodionova TV, Nesterov AN, Fesenko EE Jr. Kinetics of formation and dissociation of gas hydrates. Russ. Chem. Rev. 2017; 86(9): 845–869.

  7. Manakov AYu, Duchkov AD. Laboratory modeling of hydrate formation in rock specimens (a review). Russian Geology and Geophysics [Geologiya i geofizika]. 2017; 58(2): 240–252.

  8. Istomin VA, Chuvilin EM, Bukhanov BA, et al. Natural gas extraction method from gas hydrate deposit. RU2693983 (Patent) 2019. (In Russian)

  9. Khlebnikov VN, Vinokurov VA, Semenov AP, Gushchin PA. Method of natural gas production from hydrates. RU2607849 (Patent) 2016. (In Russian)

  10. Shostak NA, Zaporozhets EP. Calculations of Hydrate Processes. Krasnodar, Russia: Publishing House – Yug; 2018. (In Russian)

  11. Duchkov AD, Zheleznyak MN, Sokolova LS, Semenov VP. Methane and carbon dioxide hydrate stability zones in the sedimentary cover of the Vilyui syneclise. Earth's Cryosphere. 2019; 23(6): 19–22.

  12. Basniev KS, Adzynova FA. Messoyakha gas hydrate field. Status and development prospects. Oil and Gas Technologies [Tekhnologii nefti i gaza]. 2015; 5(100): 14–16. (In Russian)

  13. Vorob'yev AE. Prospects of nanotechnologies of developing gaseous-hydrate resources of the Russian Arctic shelf. Vestnik of MSTU [Vestnik MGTU]. 2016; 19(1–1): 70–81. (In Russian)

  14. Obzhirov AI, Telegin YuA, Boloban AV. Methane fluxes and gas hydrate in the Okhotsk Sea. Underwater Investigations and Robotics [Podvodnye issledovaniya i robototekhnika]. 2015; 19(1): 56–63. (In Russian)

  15. Shagapov VSh, Chiglintseva AS, Rusinov AA, Tazetdinov BI. On the migration of a single gas bubble in water. High Temp. 2017; 55(3): 414–419.

  16. Shagapov VS, Chiglintseva AS, Rusinov AA. Theoretical modeling of gas extraction from a partially gas-saturated porous gas-hydrate reservoir with respect to thermal interactions with surrounding rocks. Theor. Found. Chem. Eng. [Teoreticheskie osnovy himicheskoj tekhnologii]. 2016; 50(4): 449–459.

  17. Bondarev EA, Rozhin II, Argunova KK. Features of mathematical modeling of natural gas production and transport systems in the Russia's arctic zone. Journal of Mining Institute [Zapiski Gornogo instituta]. 2017; 228: 705–716.

  18. Bondarev EA, Rozhin II, Argunova KK. Generalized mathematical model of hydrate formation in gas pipelines. J. Appl. Mech. Tech. Phy. 2019; 60(3): 503–509.

  19. Zhang C, Korobkov GE, Yanchushka AP. Molecular thermodynamic method to determinine existence of hydrates in the main gas pipeline. Oil & Gas Technologies. 2017; 109(2): 59–64. (In Russian)

  20. Kholod VV, Yasyan YuP, Zhivaev AA. The importance of selected equation of state in hysys for calculating the required methanol concentration in hydrocarbon gas to suppress hydrate formation in low-temperature processes. Equipment and Technologies for Oil and Gas Complex [Oborudovanie i tekhnologii dlya neftegazovogo kompleksa]. 2020; 117(3): 87–94. (In Russian)

  21. Duchkov AD, Golikov NA, Duchkov AA, et al. Equipment for the studies of the acoustic properties of hydrate-containing samples in laboratory conditions. Seismic Instruments [Sejsmicheskie pribory]. 2016; 52(1): 70–78.

  22. Duchkov AD, Duchkov AA, Manakov AYu, et al. Laboratory modeling and measurement of the acoustic properties of methane-bearing rock samples.


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