A Systematic Review of the Effects of Nanofluids on Asphaltene Instability Control in the Oil Industry
Keywords:
Nanofluids, Asphaltene, oil Industry, Deposition, ControlAbstract
Asphaltenes are heavy and polar compounds found in crude oil that, under certain conditions, precipitate and cause issues such as pipeline blockages, reduced production efficiency, and increased operational costs. Traditional methods for asphaltene removal include the use of chemical inhibitors, heating, filtration, and altering operational conditions. However, these approaches often face challenges such as high costs, significant energy consumption, and negative environmental impacts. In contrast, nanofluids, as a modern technology, play a significant role in controlling asphaltenes due to their unique features such as high specific surface area, nanoscale size, and the ability to interact with various substances. Silica and alumina nanoparticles reduce surface free energy and prevent asphaltene aggregation, titania nanoparticles possess photocatalytic properties for asphaltene degradation, carbon nanotubes and graphene offer high adsorption capacity, and magnetic nanoparticles provide easy separation—making them all efficient options.
Nanofluids not only help reduce asphaltene instability but also improve the rheological properties of oil and lower operational costs. However, challenges such as high production costs, scalability, and environmental impacts require further research. Overall, nanofluids, as an innovative and sustainable solution, have brought a transformation to the oil industry.
Downloads
References
[1] Leontaritis KJ, Mansoori GA. Asphaltene flocculation during oil production and processing: a
thermodynamic colloidal model. SPE International 1987; 26(2): 17-24.
[2] Hammami A, et al. Asphaltene precipitation from live oils: An experimental investigation of
onset conditions and reversibility. Energy & Fuels 2000; 14(3): 501-508.
[3] Wasan DT, Nikolov AD. Spreading of nanofluids on solids. Nature 2003; 423(6936): 156-160.
[4] Kang W, et al. Silica nanoparticles for stabilizing asphaltene in crude oil. Journal of Petroleum
Science and Engineering 2009; 68(1-2): 13-20.
[5] Ali M, et al. Alumina nanoparticles as asphaltene inhibitors in porous media. Fuel 2016; 175: 1-
9.
[6] Srivastava S, et al. Carbon nanotubes as asphaltene inhibitors: A molecular dynamics study. Fuel
2019; 253: 1-9.
[7] Wang J, et al. Magnetic Fe₃O₄ nanoparticles for asphaltene adsorption. Energy & Fuels 2020;
34(5): 6230-6239.
[8] Zhang Z, et al. Environmental risks of nanofluids in oil recovery: A review. Journal of Hazardous
Materials 2021; 402: 123-135.
[9] Kiani S, et al. Hybrid nanofluids for enhanced asphaltene inhibition. Colloids and Surfaces A
2021; 625: 126-135.
[10] Zhang L, et al. A critical review on nanofluids for asphaltene control. Applied Energy 2023; 330:
120-140.
