References
- Bogdanov II, Torres JA. Corre B. Numerical simulation of electromagnetic driven heavy oil recovery. 18th SPE Improved Oil Recovery Symposium; 2012 April 14–18; Tulsa, OK; SPE Paper 154140; Available from: http://dx.doi.org/10.2118/154140-MS
- Davletbaev A, Kovaleva LA. Simulation of high-viscosity oil production using electromagnetic radiation combined with hydraulic fracturing of formation. High Temp. 2014;52:900–906. doi:10.1134/S0018151X14060078.
- Davletbaev A, Kovaleva LA, Babadagli T. Heavy oil production by electromagnetic heating in hydraulically fractured wells. Energy Fuels. 2014;28:5737–5744. doi:10.1021/ef5014264.10.1021/ef5014264
- Dunia R, Edgar TF. Study of heavy crude oil flows in pipelines with electromagnetic heaters. Energy Fuels 2012;26:4426–4437. doi:10.1021/ef300537e.10.1021/ef300537e
- Khabibullin IL, Khamitov AT, Nazmutdinov FF. Modeling of heat and mass transfer in porous media at phase transitions initiated by microwave heating. High Temp. 2014;52:697–702. doi:10.1134/S0018151X14040117.
- Koch A, Sotskiy S, Mustafina D, et al. Mechanism of heavy oil recovery driven by electromagnetic inductive heating. 2013 SPE Heavy Oil Conference-Canada; June 11–13; Calgary; SPE 165507.
- Hollmann TH, Chapiro G, Heller K, et al. EM stimulated water flooding in heavy oil recovery. 2014 World Heavy Oil Congress; March 5–7; New Orleans, LA; Paper WHOC14–251.
- Trautman M, Macfarlane B. Experimental and numerical simulation results from a radio frequency heating test in native oil sands at the North Steepbank Mine. 2014 World Heavy Oil Congress; March 5–7; New Orleans, LA; Paper WHOC14-301.
- Bera A, Babadagli T. Status of electromagnetic heating for enhanced heavy oil/bitumen recovery and future prospects: a review. Appl. Energy. 2015;151:206–226.
- Sayakhov FL, Kovaleva LA, Fatichov MA, et al. Analysis of influencing of a RF EM field on diffusion processes in saturated porous mediums. Electronic Processing of Stuffs; Kishinev; 1975. p. 59–61.
- Nigmatulin RI, Sayakhov FL, Kovaleva LA. Cross transport phenomena in disperse systems interacting with a high-frequency electromagnetic field. Dokl. Phys.. 2001;46:215–218.10.1134/1.1364733
- Sayakhov FL, Kovaleva LA, Nasyrov NM, et al. The influence of a high-frequency electromagnetic field on the crossover transfer effects in multicomponent systems. Magn. Gidrodin. 1998;34:148–157.
- Kovaleva L, Davletbaev A, Babadagli T, et al. Effects of electrical and radio-frequency electromagnetic heating on the mass-transfer process during miscible injection for heavy-oil recovery. Energy Fuels. 2011;25:482–486.10.1021/ef1009428
- Sayakhov FL, Kovaleva LA, Fatykhov MA, et al. RU Patent 1,824,983. 1997.
- Davletbaev A, Kovaleva LA, Nasyrov NM. Numerical simulation of injection of a solvent into a production well under electromagnetic action. Fluid Dyn. 2008;43:583–589.10.1134/S0015462808040108
- Davletbaev A, Kovaleva LA, Nasyrov NM. An investigation of the processes of heat and mass transfer in a multilayer medium under conditions of injection of a miscible agent with simultaneous electromagnetic stimulation. High Temp. 2009;47:574–579.10.1134/S0018151X09040166
- Davletbaev A, Kovaleva LA, Zinnatullin R. Development method of high-viscous oil deposit. RU Patent 2,454,532. 2012.
- Abernethy ER. Production increase of heavy oils by electromagnetic heating. J. Can. Pet. Technol. 1976;15:91–99.
- Nasyrov NM. Some problems of heat and mass transfer with phase transitions of unconventional hydrocarbons to electromagnetic irradiation [ Dissertation of Doctor of Physical and Mathematical Sciences]. Ufa: Bashkir State University; 1992; p. 163.
- Cinco LH, Samaniego VF, Dominguez AN. Transient pressure behavior for a well with a finite-conductivity vertical fracture. Soc. Petrol. Eng. J. 1978;18:253–264. doi:10.2118/6014-PA.