Modeling of bacterium influence on methane concentration in underground storage of hydrogen
Кілттік сөздер:
Porous media, Hydrogen, Bacteria, Neuston, Chemotaxis.Population dynamics, OscillationsАннотация
The problem of underground hydrogen gas mixture storage is that unlike natural gas, hydrogen gas mixture undergoes chemical changes in underground storage and thus the concentration of hydrogen and carbon dioxide is reduced, and the concentration of methane increases. It has been found that these changes occur because of the activity of methanogenic bacteria populations inhabiting in a reservoir. This chemical activity, which caused by the bacterial activity, as well as gas and water flow in the reservoir causes the phenomenon of self-organization such as the occurrence of autowave spatial structures, the dynamics of which is characterized by a multiplicity of different scenarios, including the occurrence of chaos and the jump from one scenario to another. In this paper we developed a qualitative theory of self-organization scenarios in the underground hydrogen storage depending on the external and internal parameters. Development of the theory and computer models of transport in underground hydrogen storage will be based on the relating of models of multiphase composite flows in porous media with model of dynamics of bacterial populations which will be based on mechanism of chemotaxis (internal chemical mechanism by which bacteria are able to detect the presence of nutrients in the distance and move in that direction).Библиографиялық сілтемелер
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underground storage of hydrogen: natural self-organisation. In: Proc. ECMOR-XIII: 13th European Conference on the Mathematics of Oil Recovery, 10-13 September 2012 Biarritz, France, Ed. EAGE, 2012, paper B09.
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[13] 13. Merkin, J.H, Needham, D.J, Scott, S.K. On the creation, growth and extinction of oscillatory solutions for a simple pooled
chemical reaction scheme. SIAM J. Appl. Math 47, 1040-1060 (1987)
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[2] 2. Simbeck D.R. CO2 capture and storage—the essential bridge to the hydrogen economy. Energy 29, 1633–1641 (2004)
[3] 3. Zittel W, Wurster R. Hydrogen in the energy sector. Laudwig-Bolkow Systemtechnik GmbH, 7, Aug., 1996.
[4] 4. Taylor, J.B., Alderson, J.E.A.,Kalyanam, K.M., Lyle, A.B., Phillips, L.A. Technical and economic assessment of methods
for the storage of large quantities of hydrogen. Int. J. Hydrog. Energy 11(1), 5–22 (1986)
[5] 5. Bulatov G.G. Underground storage of hydrogen. Ph.D. Thesis, Moscow Gubkin Oil and Gas University, 1979 (in Russian).
[6] 6. Carden P.O.,Paterson L. Physical, chemical and energy aspects of underground hydrogen storage. International Journal
of Hydrogen Energy, 4, Issue 6, 1979: P 559-569.
[7] 7. Buzek F., Onderka V., Vancura P., Wolf I. Carbon isotope study of methane production in a town gas storage reservoir.
Fuel 73(5), 1994: 747–752.
[8] 8. Smigai P., Greksak M., Kozankova J., Buzek F., Onderka V., Wolf I. Methanogenic bacteria as a key factor involved in
changes of town gas in an underground reservoir. FEMS Microbiol. Ecol. 73, 1990: P 221–224.
[9] 9. Panfilov M.,Gravier G., Fillacier S. Underground storage of H2 and H2-CO2-CH4 mixtures. In: Proc. ECMOR-X: 10th
European Conference on the Mathematics of Oil Recovery, 4-7 September 2006 Amsterdam, the Netherlands, Ed. EAGE, 2006, paper A003.
[10] 10. Panfilov M. Undeground storage of hydrogen: self-organisation and methane generation. Transport in Porous Media, 85, 2010: P 841 - 865.
[11] 11. Toleukhanov A., Panfilov M., Panfilova I., Kaltayev A. Bio-reactive two-phase transport and population dynamics in
underground storage of hydrogen: natural self-organisation. In: Proc. ECMOR-XIII: 13th European Conference on the Mathematics of Oil Recovery, 10-13 September 2012 Biarritz, France, Ed. EAGE, 2012, paper B09.
[12] 12. Turing A.M. The chemical basis of morphogenesis. Philos. Trans. R. Soc. London, Ser B, B 237, 1952: 37 - 72.
[13] 13. Merkin, J.H, Needham, D.J, Scott, S.K. On the creation, growth and extinction of oscillatory solutions for a simple pooled
chemical reaction scheme. SIAM J. Appl. Math 47, 1040-1060 (1987)
[14] 14. Schnakenberg J. Simple chemical reaction systems with limit cycle behaviour. J. Theor. Biol. 81(3), 389-400 (1979)
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Как цитировать
Toleukhanov, A., Panfilov, M., & Kaltayev А. (2015). Modeling of bacterium influence on methane concentration in underground storage of hydrogen. Қазұу Хабаршысы. Математика, механика, информатика сериясы, 85(2). вилучено із https://bm.kaznu.kz/index.php/kaznu/article/view/288
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