References
- Ayatollahi, S., and Zerafat, M.-M. (2012). Nanotechnology-assisted EOR techniques: new solutions to old challenges [M].
- Brodie, J., Jhaveri, B., Moulds, T., and Hetland, S.-M. (2012). Review of gas injection projects in BP. SPE Improved Oil Recovery Symposium 1.
- Chu, Y., Fan, C., Zhang, Q., Zan, C., Ma, D., Jiang, H. (2014). The oxidation of heavy oil to enhance oil recovery: The numerical model and the criteria to describe the low and high temperature oxidation. Chem. Eng. J. 248(4):422–429.
- Ferguson, M.-A., Mamora, D.-D., and Goite, J.-G. (2001). Steam-propane injection for production enhancement of heavy Morichal oil.
- Galarraga, C.-E., and Pereiraalmao, P. (2010). Hydrocracking of athabasca bitumen using submicronic multimetallic catalysts at near in-reservoir conditions. Energy Fuels 24(24).
- Gui, B., Yang, Q.-Y., and Wu, H.-J. (2010). Study of the effects of low-temperature oxidation on the chemical composition of a light crude oil [J]. Energy Fuels 24:1139–1145.
- Gutierrez, D., Skoreyko, F., Moore, R. G., Mehta, S. A., and Ursenbach, M. G. (2009). The challenge of predicting field performance of air injection projects based on laboratory and numerical modelling. J. Can. Pet. Technol. 48(4):23–33.
- Hashemi, R., Nassar, N.-N., and Almao, P.-P. (2013). In situ upgrading of athabasca bitumen using multimetallic ultradispersed nanocatalysts in an oil sands packed-bed column: Part 1. Produced liquid quality enhancement. Energy Fuels 28(2):1338–1350.
- He, B., Chen, Q., Castanier, L.-M., and Kovscek, A.-R. (2005). Improved in-situ combustion performance with metallic salt additives.
- Husein, M.-M., and Alkhaldi, S.-J. (2014). In situ preparation of alumina nanoparticles in heavy oil and their thermal cracking performance. Energy Fuels 28(10):6563–6569.
- Khansari, Z., Kapadia, P., Mahinpey, N., and Gates, I.-D. (2014). A new reaction model for low temperature oxidation of heavy oil: Experiments and numerical modeling. Energy. 64(1):419–428.
- Li, J., Wei, Y., Tang, X., Liu, X., and Deng, L. (2016). Catalytic effect of zinc naphthenate on the heavy oil low-temperature oxidation in an air injection process. Pet. Sci. Technol. 34(9):813–818.
- Nassar, N.-N. (2010). Asphaltene adsorption onto alumina nanoparticles: kinetics and thermodynamic studies. Energy Fuels 24(8):4116–4122.
- Ramirez-Garnica, M.-A., Mamora, D.-D., Nares, R., Schacht-Hernandez, P., Mohammad, A.A.-A., and Cabrera, M. (2007). Increase heavy-oil production in combustion tube experiments through the use of catalyst.
- Ren, S.-R., Greaves, M., and Rathbone, R.-R. (2002). Air injection LTO process: An IOR technique for light-oil reservoirs. SPE J. 7(1):90–99.
- Turta, A.-T., and Singhal, A.-K. (2001). Reservoir engineering aspects of light-oil recovery by air injection. SPE Reserv. Eval. Eng. 4(4):336–344.
- Wang, J., Wang, T., Feng, C., Yang, C., Chen, Z., and Lu, G. (2015). Catalytic effect of transition metallic additives on the light oil low-temperature oxidation reaction. Energy Fuels 29(6):150526172106007.
- Xu, C.-M., and Yang, C.-H. (2009). Process fundamentals and field demonstration of wheat straw enhanced biodegradation of petroleum. J. Environ. Sci. 30(1):237.
- Yang, S., Jin, L., Kong, Q., and Li, L. (1988). Advanced Engineering Mechanics. Beijing, China: Higher Education Press, vol. 156–157, pp. 222–223 (in Chinese).
- Yu, H., Yang, B., Xu, G., Wang, J., Ren, S., Lin, W. (2008). Air foam injection for IOR: from laboratory to field implementation in ZhongYuan oilfield china. Paper presented at the Visual Information Engineering, 2008. VIE 2008. 5th International Conference on.
- Zhang, L., Deng, J., Wang, L., Chen, Z., Ren, S., and Hu, C. (2015). Low-temperature oxidation characteristics and its effect on the critical coking temperature of heavy oils. Energy Fuels 29(2):150114111350000.