[27] Ansari MA,

Khan HM, Alzohairy MA, Jalal M, Ali SG, Pal R, et al. Green synthesis of Al2O3 nanoparticles and their bactericidal potential against clinical isolates of multi-drug resistant Pseudomonas aeruginosa. World J Microbiol Biotechnol. 2015 Jan 11;31(1):153-164.

[28] Senthilkumar S, Rajendran A. Biosynthesis of TiO2 nanoparticles using Justicia gendarussa leaves for photocatalytic and toxicity studies. Res Chem Intermed. 2018;44(10):5923-5940.

[29] Fridman AA. Plasma chemistry. Cambridge; New York: Cambridge University Press; 2008.

[30] Petitpas G, Rollier J-D, Darmon A, Gonzalez-Aguilar J, Metkemeijer R, Fulcheri L. A comparative study of non-thermal plasma assisted reforming technologies. Int J Hydrogen Energy . 2007;32(14):2848-2867.

[31] Acayanka E, Tarkwa J-B, Nchimi KN, Voufouo SAY, Tiya-Djowe A, Kamgang GY, et al. Grafting of N-doped titania nanoparticles synthesized by the plasma-assisted method on textile surface for sunlight photocatalytic self-cleaning applications. Surfaces and Interfaces. 2019;

[32] Acayanka E, Kuete DS, Kamgang GY, Nzali S, Laminsi S, Ndifon PT. Synthesis, Characterization

**148**

*Advances in Microfluidics and Nanofluids*

[1] Coey JMD, Venkatesan M, Xu H.

[9] Azurdia JA, McCrum A, Laine RM. Systematic synthesis of mixed-metal oxides in NiO–Co3O4, NiO–MoO3, and NiO–CuO systems via liquid-feed flame spray pyrolysis. J Mater Chem.

MacManus-Driscoll JL. Synthesis and characterisation of nanocrystalline iron oxides via ultrasonic spray assisted chemical vapour deposition. J Phys Conf

[11] Suslick KS. Sonochemistry. Science (80). 1990 Mar 23;247(4949):1439-45.

Gedanken A. Sonochemical Synthesis and Characterization of Nanometer-Size Transition Metal Oxides from Metal Acetates. Chem Mater. 2000 Aug

[13] Díez-García MI, Manzi-Orezzoli V, Jankulovska M, Anandan S, Bonete P, Gómez R, et al. Effects of Ultrasound Irradiation on the Synthesis of Metal Oxide Nanostructures. Phys Procedia.

Ser. 2006 Feb 22;26(1):304-307.

[12] Kumar RV, Diamant Y,

1;12(8):2301-2305.

2015;63:85-90.

2019;248:61-87.

[14] Shi W, Song S, Zhang H. Hydrothermal synthetic strategies of inorganic semiconducting nanostructures. Chem Soc Rev.

[15] Ota J, Srivastava SK. Polypyrrole Coating of Tartaric Acid-Assisted Synthesized Bi2S3 Nanorods. J Phys Chem C. 2007 Aug 1;111(33):12260-12264.

[16] Yuan G, Cao Y, Zan N, Schulz HM, Gluyas J, Hao F, et al. Coupled mineral alteration and oil degradation in thermal oil-water-feldspar systems and implications for organic-

inorganic interactions in hydrocarbon reservoirs. Geochim Cosmochim Acta.

2013;42(13):5714-5743.

2008;18(27):3249-3258.

[10] Chao LT, Wei M,

Oxides. Functional Metal Oxides.

[2] Yuan C, Wu H Bin, Xie Y, Lou XW (David). Mixed Transition-Metal Oxides: Design, Synthesis, and Energy-Related Applications. Angew Chemie Int Ed [Internet]. 2014 Feb

[3] Fang J, Xuan Y, Li Q. Preparation of three-dimensionally ordered macroporous perovskite materials.

Introduction to Magnetic

2013. p. 1-49.

**References**

3;53(6):1488-504.

1;56:2156-2161.

2015. p. 113-142.

Chinese Sci Bull. 2011 Jul

[4] Sadakane M, Ueda W. Three-Dimensionally Ordered Macroporous (3DOM) Perovskite Mixed Metal Oxides. In: Perovskites and Related Mixed Oxides. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA;

[5] Merkel TJ, Herlihy KP, Nunes J, Orgel RM, Rolland JP, DeSimone JM. Scalable, shape-specific, top-down fabrication methods for the synthesis of engineered colloidal particles. Langmuir.

2010 Aug;26(16):13086-13096.

[6] Gerberich WW, Jungk JM,

[7] Zhao X, Zheng B, Li C, Gu H. Acetate-derived ZnO ultrafine particles synthesized by spray pyrolysis. Powder

[8] Azurdia J, Marchal J, Laine R. Synthesis and Characterization of Mixed-Metal Oxide Nanopowders Along the CoOx–Al2O3 Tie Line Using Liquid-Feed Flame Spray Pyrolysis. J Am Ceram

Soc. 2006 Sep 1;89:2749-2756.

Technol. 1998;100(1):20-23.

Ltd; 2003. p. 211-220.

Mook WM. The Bottom-Up Approach To Materials By Design. In: Meyers MA, Ritchie RO, Sarikaya MBT-N and MD of AM, editors. Oxford: Elsevier Science

and Photocatalytic Application of TiO2/SnO2 Nanocomposite Obtained Under Non-thermal Plasma Condition at Atmospheric Pressure. Plasma Chem Plasma Process. 2016 May 21;36(3):799-811.

[33] Acayanka E, Tarkwa J-B, Nchimi KN, Voufouo SAY, Tiya-Djowe A, Kamgang GY, et al. Grafting of N-doped titania nanoparticles synthesized by the plasma-assisted method on textile surface for sunlight photocatalytic self-cleaning applications. Surfaces and Interfaces. 2019 Dec;17:100361.

[34] Chemical Fundamentals of Hydrometallurgy. Hydrometallurgy. 2013. p. 21-64. (Wiley Online Books).

[35] Manivasakan P, Rajendran V, Rauta PR, Sahu BB, Panda BK. Direct Synthesis of Nano Alumina from Natural Bauxite. Adv Mater Res. 2009 Apr 1;67:143-148.

[36] Rayzman V, Aturin A, Pevzner I, Sizyakov V, Ni L, Filipovich I. Extracting Silica and Alumina from Low-Grade Bauxite. JOM. 2003 Jan 8;55:47-50.

[37] Akoh H, Tsukasaki Y, Yatsuya S, Tasaki A. Magnetic properties of ferromagnetic ultrafine particles prepared by vacuum evaporation on running oil substrate. J Cryst Growth. 1978 Dec 1;45:495-500.

[38] Phuoc TX, Soong Y, Chyu MK. Synthesis of Ag-deionized water nanofluids using multi-beam laser ablation in liquids. Opt Lasers Eng. 2007 Dec;45(12):1099-1106.

[39] Everett DH. Chapter 2. Why are Colloidal Dispersions Stable? I Basic Principles. In 1988. p. 16-29.

[40] Bolukbasi A, Ciloglu D. Pool boiling heat transfer characteristics of vertical cylinder quenched by SiO2–water nanofluids. Int J Therm Sci. 2011 Jun 1;50(6):1013-1021.

[41] Darzi AAR, Farhadi M, Sedighi K, Shafaghat R, Zabihi K. Experimental investigation of turbulent heat transfer and flow characteristics of SiO2/water nanofluid within helically corrugated tubes. Int Commun Heat Mass Transf. 2012 Nov 1;39(9):1425-1434.

[42] Kumar RS, Sharma T. Stability and rheological properties of nanofluids stabilized by SiO2 nanoparticles and SiO2-TiO2 nanocomposites for oilfield applications. Colloids Surfaces A Physicochem Eng Asp. 2018 Feb;539:171-183.

[43] Nguele R, Sreu T, Inoue H, Sugai Y, Sasaki K. Enhancing Oil Production Using Silica-Based Nanofluids: Preparation, Stability, and Displacement Mechanisms. Ind Eng Chem Res. 2019 Aug;58(32):15045-15060.

[44] Suslick KS, Didenko Y, Fang MM, Hyeon T, Kolbeck KJ, McNamara III WB, et al. Acoustic cavitation and its consequences. Philos Trans R Soc A. 1999;357(1927):335-353.

[45] Xuan Y, Li Q. Heat transfer enhancement of nanofluids. Int J Heat Fluid Flow. 2000 Feb 1;21(1):58-64.

[46] Garg J, Poudel B,

Chiesa M, Gordon JB, Ma JJ, Wang JB, et al. Enhanced thermal conductivity and viscosity of copper nanoparticles in ethylene glycol nanofluid. J Appl Phys. 2008 Apr 2;103(7):074301.

[47] Ngo I, Sasaki K, Nguele R, Sugai Y. Formation Damage Induced by Water-Based Alumina Nanofluids during Enhanced Oil Recovery: Influence of Postflush Salinity. ACS Omega. 2020 Oct 27;5(42):27103-27112.

[48] Ali N, Teixeira JA, Addali A. A Review on Nanofluids: Fabrication, Stability, and Thermophysical Properties. J Nanomater. 2018; 2018:1-33.

**151**

*Nanocomposite and Nanofluids: Towards a Sustainable Carbon Capture, Utilization, and Storage*

[57] Nguele R, Ghulami MR, Sasaki K, Said-Al Salim H,

[59] Ngo I, Srisuriyachai F,

Jul 1;62(4):188-198.

[60] Nguele R, Sasaki K,

2;293(12):3487-3497.

Aug;157:1115-1129.

Using Sodium Dodecylbenzene

Widiatmojo A, Sugai Y, et al. Asphaltene Aggregation in Crude Oils during Supercritical Gas Injection. Energy and Fuels. 2016 Feb;30(2):1266-1278.

[58] Nguele R, Sasaki K, Ghulami MR, Sugai Y, Nakano M. Pseudo-phase equilibrium of light and heavy crude oils for enhanced oil recovery. J Pet Explor Prod Technol. 2016 Sep 20;6(3):419-432.

Sasaki K, Sugai Y, Nguele R. Effects of Reversibility on Enhanced Oil Recovery

Sulfonate (SDBS). J Japan Pet Inst. 2019

Salim HS, Sugai Y. Physicochemical and microemulsion properties of dimeric quaternary ammonium salts with trimethylene spacer for enhanced oil recovery. Colloid Polym Sci. 2015 Dec

[61] Nguele R, Sasaki K, Sugai Y, Said Al-Salim H, Ueda R. Mobilization and displacement of heavy oil by cationic microemulsions in different sandstone

formations. J Pet Sci Eng. 2017

[62] Santanna VC, Curbelo FDS, Castro Dantas TN, Dantas Neto AA, Albuquerque HS,

2009 Jun;66(3-4):117-120.

Garnica AIC. Microemulsion flooding for enhanced oil recovery. J Pet Sci Eng.

[63] Nguele R, Sasaki K, Salim HS-A, Sugai Y, Widiatmojo A, Nakano M. Microemulsion and phase behavior properties of (Dimeric ammonium surfactant salt – heavy crude oil – connate water) system. J Unconv Oil Gas Resour. 2016 Jun;14:62-71.

[64] Bera A, Mandal A. Microemulsions: a novel approach to enhanced oil

*DOI: http://dx.doi.org/10.5772/intechopen.95838*

[49] Kato H, Nakamura A, Noda N. Determination of size distribution of silica nanoparticles: A comparison of scanning electron microscopy, dynamic light scattering, and flow field-flow fractionation with multiangle light scattering methods. Mater Express.

[50] Sidik NAC, Mohammed HA, Alawi OA, Samion S. A review on preparation methods and challenges of nanofluids. Int Commun Heat Mass

Transf. 2014 May;54:115-125.

[51] Fazeli SA, Hosseini Hashemi SM, Zirakzadeh H, Ashjaee M. Experimental and numerical investigation of heat transfer in a miniature heat sink utilizing silica nanofluid. Superlattices Microstruct. 2012 Feb 1;51(2):247-264.

[52] Pang C, Jung J-Y, Lee JW, Kang YT. Thermal conductivity measurement of methanol-based nanofluids with Al2O3 and SiO2 nanoparticles. Int J Heat Mass Transf. 2012 Oct 1;55(21-22):5597-5602.

[53] Devendiran DK, Amirtham VA. A review on preparation, characterization,

nanofluids. Renew Sustain Energy Rev.

Sugai Y, Nakano M, Imai M. Preliminary

[56] Speight JG. Petroleum asphaltenes - Part 1: Asphaltenes, resins and the structure of petroleum. Oil Gas Sci Technol. 2004;59(5):467-477.

numerical modelling of CO2 gas foaming in heavy oil and simulations of oil production from heavy oil reservoirs. Can J Chem Eng. 2016

properties and applications of

[54] Shah A, Fishwick R, Wood J, Leeke G, Rigby S, Greaves M. A review of novel techniques for heavy oil and bitumen extraction and upgrading. Energy Environ Sci. 2010;3(6):700.

2016;60:21-40.

[55] Or C, Sasaki K,

Mar;94(3):576-585.

2014;4(2):144-152.

*Nanocomposite and Nanofluids: Towards a Sustainable Carbon Capture, Utilization, and Storage DOI: http://dx.doi.org/10.5772/intechopen.95838*

[49] Kato H, Nakamura A, Noda N. Determination of size distribution of silica nanoparticles: A comparison of scanning electron microscopy, dynamic light scattering, and flow field-flow fractionation with multiangle light scattering methods. Mater Express. 2014;4(2):144-152.

*Advances in Microfluidics and Nanofluids*

and Photocatalytic Application of TiO2/SnO2 Nanocomposite Obtained Under Non-thermal Plasma Condition at Atmospheric Pressure. Plasma Chem Plasma Process. 2016 May

[41] Darzi AAR, Farhadi M, Sedighi K, Shafaghat R, Zabihi K. Experimental investigation of turbulent heat transfer and flow characteristics of SiO2/water nanofluid within helically corrugated tubes. Int Commun Heat Mass Transf.

[42] Kumar RS, Sharma T. Stability and rheological properties of nanofluids stabilized by SiO2 nanoparticles and SiO2-TiO2 nanocomposites for oilfield applications. Colloids Surfaces

[43] Nguele R, Sreu T, Inoue H, Sugai Y, Sasaki K. Enhancing Oil Production Using Silica-Based Nanofluids:

Preparation, Stability, and Displacement Mechanisms. Ind Eng Chem Res. 2019

[44] Suslick KS, Didenko Y, Fang MM, Hyeon T, Kolbeck KJ, McNamara III WB, et al. Acoustic cavitation and its consequences. Philos Trans R Soc A.

Chiesa M, Gordon JB, Ma JJ, Wang JB, et al. Enhanced thermal conductivity and viscosity of copper nanoparticles in ethylene glycol nanofluid. J Appl Phys.

[47] Ngo I, Sasaki K, Nguele R, Sugai Y. Formation Damage Induced by Water-Based Alumina Nanofluids during Enhanced Oil Recovery: Influence of Postflush Salinity. ACS Omega. 2020

2012 Nov 1;39(9):1425-1434.

A Physicochem Eng Asp. 2018

Aug;58(32):15045-15060.

1999;357(1927):335-353.

[46] Garg J, Poudel B,

2008 Apr 2;103(7):074301.

Oct 27;5(42):27103-27112.

2018:1-33.

[48] Ali N, Teixeira JA, Addali A. A Review on Nanofluids: Fabrication, Stability, and Thermophysical Properties. J Nanomater. 2018;

[45] Xuan Y, Li Q. Heat transfer enhancement of nanofluids. Int J Heat Fluid Flow. 2000 Feb 1;21(1):58-64.

Feb;539:171-183.

[33] Acayanka E, Tarkwa J-B,

Interfaces. 2019 Dec;17:100361.

[34] Chemical Fundamentals of Hydrometallurgy. Hydrometallurgy. 2013. p. 21-64. (Wiley Online Books).

[35] Manivasakan P, Rajendran V, Rauta PR, Sahu BB, Panda BK. Direct Synthesis of Nano Alumina from Natural Bauxite. Adv Mater Res. 2009

Pevzner I, Sizyakov V, Ni L, Filipovich I. Extracting Silica and Alumina from Low-Grade Bauxite. JOM. 2003 Jan

Yatsuya S, Tasaki A. Magnetic properties of ferromagnetic ultrafine particles prepared by vacuum evaporation on running oil substrate. J Cryst Growth.

[38] Phuoc TX, Soong Y, Chyu MK. Synthesis of Ag-deionized water nanofluids using multi-beam laser ablation in liquids. Opt Lasers Eng. 2007

[39] Everett DH. Chapter 2. Why are Colloidal Dispersions Stable? I Basic

[40] Bolukbasi A, Ciloglu D. Pool boiling heat transfer characteristics of vertical cylinder quenched by SiO2–water nanofluids. Int J Therm Sci. 2011 Jun

Apr 1;67:143-148.

8;55:47-50.

[36] Rayzman V, Aturin A,

[37] Akoh H, Tsukasaki Y,

1978 Dec 1;45:495-500.

Dec;45(12):1099-1106.

1;50(6):1013-1021.

Principles. In 1988. p. 16-29.

Nchimi KN, Voufouo SAY, Tiya-Djowe A, Kamgang GY, et al. Grafting of N-doped titania nanoparticles synthesized by the plasma-assisted method on textile surface for sunlight photocatalytic self-cleaning applications. Surfaces and

21;36(3):799-811.

**150**

[50] Sidik NAC, Mohammed HA, Alawi OA, Samion S. A review on preparation methods and challenges of nanofluids. Int Commun Heat Mass Transf. 2014 May;54:115-125.

[51] Fazeli SA, Hosseini Hashemi SM, Zirakzadeh H, Ashjaee M. Experimental and numerical investigation of heat transfer in a miniature heat sink utilizing silica nanofluid. Superlattices Microstruct. 2012 Feb 1;51(2):247-264.

[52] Pang C, Jung J-Y, Lee JW, Kang YT. Thermal conductivity measurement of methanol-based nanofluids with Al2O3 and SiO2 nanoparticles. Int J Heat Mass Transf. 2012 Oct 1;55(21-22):5597-5602.

[53] Devendiran DK, Amirtham VA. A review on preparation, characterization, properties and applications of nanofluids. Renew Sustain Energy Rev. 2016;60:21-40.

[54] Shah A, Fishwick R, Wood J, Leeke G, Rigby S, Greaves M. A review of novel techniques for heavy oil and bitumen extraction and upgrading. Energy Environ Sci. 2010;3(6):700.

[55] Or C, Sasaki K,

Sugai Y, Nakano M, Imai M. Preliminary numerical modelling of CO2 gas foaming in heavy oil and simulations of oil production from heavy oil reservoirs. Can J Chem Eng. 2016 Mar;94(3):576-585.

[56] Speight JG. Petroleum asphaltenes - Part 1: Asphaltenes, resins and the structure of petroleum. Oil Gas Sci Technol. 2004;59(5):467-477.

[57] Nguele R, Ghulami MR, Sasaki K, Said-Al Salim H, Widiatmojo A, Sugai Y, et al. Asphaltene Aggregation in Crude Oils during Supercritical Gas Injection. Energy and Fuels. 2016 Feb;30(2):1266-1278.

[58] Nguele R, Sasaki K, Ghulami MR, Sugai Y, Nakano M. Pseudo-phase equilibrium of light and heavy crude oils for enhanced oil recovery. J Pet Explor Prod Technol. 2016 Sep 20;6(3):419-432.

[59] Ngo I, Srisuriyachai F, Sasaki K, Sugai Y, Nguele R. Effects of Reversibility on Enhanced Oil Recovery Using Sodium Dodecylbenzene Sulfonate (SDBS). J Japan Pet Inst. 2019 Jul 1;62(4):188-198.

[60] Nguele R, Sasaki K,

Salim HS, Sugai Y. Physicochemical and microemulsion properties of dimeric quaternary ammonium salts with trimethylene spacer for enhanced oil recovery. Colloid Polym Sci. 2015 Dec 2;293(12):3487-3497.

[61] Nguele R, Sasaki K, Sugai Y, Said Al-Salim H, Ueda R. Mobilization and displacement of heavy oil by cationic microemulsions in different sandstone formations. J Pet Sci Eng. 2017 Aug;157:1115-1129.

[62] Santanna VC, Curbelo FDS, Castro Dantas TN, Dantas Neto AA, Albuquerque HS, Garnica AIC. Microemulsion flooding for enhanced oil recovery. J Pet Sci Eng. 2009 Jun;66(3-4):117-120.

[63] Nguele R, Sasaki K, Salim HS-A, Sugai Y, Widiatmojo A, Nakano M. Microemulsion and phase behavior properties of (Dimeric ammonium surfactant salt – heavy crude oil – connate water) system. J Unconv Oil Gas Resour. 2016 Jun;14:62-71.

[64] Bera A, Mandal A. Microemulsions: a novel approach to enhanced oil

recovery: a review. J Pet Explor Prod Technol. 2015 Sep;5(3):255-268.

[65] Thomas S. Enhanced oil recovery-an overview. Oil Gas Sci Technol. 2008;63(1):9-19.

[66] Ansah EO, Sugai Y, Nguele R, Sasaki K. Integrated microbial enhanced oil recovery (MEOR) simulation: Main influencing parameters and uncertainty assessment. J Pet Sci Eng. 2018 Dec;171:784-793.

[67] Purwasena IA, Astuti DI, Syukron M, Amaniyah M, Sugai Y. Stability test of biosurfactant produced by Bacillus licheniformis DS1 using experimental design and its application for MEOR. J Pet Sci Eng. 2019 Dec 1;183.

[68] Ansah EO, Vo Thanh H, Sugai Y, Nguele R, Sasaki K. Microbe-induced fluid viscosity variation: field-scale simulation, sensitivity and geological uncertainty. J Pet Explor Prod Technol. 2020 Jun 1;10(5):1983-2003.

[69] Ogolo NA,

Olafuyi OA, Onyekonwu MO. Enhanced Oil Recovery Using Nanoparticles. In: SPE Saudi Arabia Section Technical Symposium and Exhibition. Society of Petroleum Engineers; 2012.

[70] Hendraningrat L, Li S, Torsæter O. A coreflood investigation of nanofluid enhanced oil recovery. J Pet Sci Eng. 2013 Nov;111:128-138.

[71] Li S, Hendraningrat L, Torsaeter O. Improved Oil Recovery by Hydrophilic Silica Nanoparticles Suspension: 2-Phase Flow Experimental Studies. In: International Petroleum Technology Conference. International Petroleum Technology Conference; 2013.

[72] Giraldo J, Benjumea P, Lopera S, Cortés FB, Ruiz MA. Wettability Alteration of Sandstone Cores by Alumina-Based Nanofluids. Energy & Fuels. 2013 Jul;27(7):3659-3665.

[73] Kothari N, Raina B, Chandak KB, Iyer V, Mahajan HP. Application Of Ferrofluids For Enhanced Surfactant Flooding In IOR. In: SPE EUROPEC/ EAGE Annual Conference and Exhibition. Society of Petroleum Engineers; 2010.

[74] Tarek M, El-Banbi AH. Comprehensive Investigation of Effects of Nano-Fluid Mixtures to Enhance Oil Recovery. In: SPE North Africa Technical Conference and Exhibition. Society of Petroleum Engineers; 2015.

[75] Haroun MR, Alhassan S, Ansari AA, Al Kindy NAM, Abou Sayed N, Abdul Kareem BA, et al. Smart Nano-EOR Process for Abu Dhabi Carbonate Reservoirs. In: Abu Dhabi International Petroleum Conference and Exhibition. Society of Petroleum Engineers; 2012. p. 1-13.

[76] Donaldson EC, Tiab DECD, Donaldson EC. Petrophysics: Theory and Practice of Measuring Reservoir Rock and Fluid Transport Properties. 2nd ed. Book. Gulf Professional Pub./ Elsevier; 2004. 898 p.

[77] Tola S, Sasaki K, Sugai Y. Wettability alteration of sandstone with zinc oxide nano-particles. In: 23rd Formation Evaluation Symposium of Japan 2017. 2017.

[78] Romero Z, Disney R, Acuna HM, Cortes F, Patino JE, Cespedes Chavarro C, et al. Application and evaluation of a nanofluid containing nanoparticles for asphaltenes inhibition in well CPSXL4. In: OTC Brasil. Offshore Technology Conference; 2013.

[79] Ibrahim HH, Idem RO. Interrelationships between asphaltene precipitation inhibitor effectiveness, asphaltenes characteristics, and precipitation behavior during n-heptane (light paraffin hydrocarbon)-induced

**153**

*Nanocomposite and Nanofluids: Towards a Sustainable Carbon Capture, Utilization, and Storage*

[87] Kannan N, Vakeesan D. Solar energy for future world: - A review. Renew Sustain Energy Rev.

[88] Tian Y, Zhao CY. A review of solar collectors and thermal energy storage in solar thermal applications. Appl Energy.

[89] Reddy KS, Kamnapure NR, Srivastava S. Nanofluid and nanocomposite applications in solar energy conversion systems for performance enhancement: a review. Int J Low-Carbon Technol. 2017

[90] Tchanche BF, Lambrinos G, Frangoudakis A, Papadakis G. Lowgrade heat conversion into power using organic Rankine cycles – A review of various applications. Renew Sustain Energy Rev. 2011;15(8):3963-3979.

[91] Axaopoulos PJ. Solar Thermal Conversion: Active Solar Systems. Simmetria Publications; 2011.

J Heat Transfer. 1999 May

[93] Akhatov JS, Mirzaev SZ, Halimov AS, Telyaev SS, Juraev ET. Study of the possibilities of thermal performance enhancement of flat plate solar water collectors by using of nanofluids as heat transfer fluid. Appl Sol Energy. 2017;53(3):250-257.

[94] Tyagi H, Phelan P,

2009 Nov;131.

Prasher R. Predicted Efficiency of a Low-Temperature Nanofluid-Based Direct Absorption Solar Collector. J Sol Energy Eng Asme - J Sol Energy Eng.

[95] Karami M, Akhavan-Bahabadi MA, Delfani S, Raisee M. Experimental investigation of CuO nanofluid-based

1;121(2):280-289.

[92] Lee S, Choi SU-S, Li S, Eastman JA. Measuring Thermal Conductivity of Fluids Containing Oxide Nanoparticles.

2016;62:1092-1105.

2013;104:538-553.

Mar;12(1):1-23.

*DOI: http://dx.doi.org/10.5772/intechopen.95838*

[80] Goual L. Petroleum Asphaltenes. In: Manar El-Sayed Abdul-Raouf, editor. Crude Oil Emulsions- Composition Stability and Characterization. InTech;

Sugai Y, Yousefi-Sahzabi A. Estimating a baseline of soil CO2 flux at CO2 geological storage sites. Environ Monit

Anggara F, Yousefi-Sahzabi A, Sugai Y, Kawamura T, Et Al. Few Considerations on Problems of CO2 Geological Storage with Carbon Circulation and Proposal of An Integrated Regional Energy System considering Low Carbon Society. J MMIJ. 2015 Aug 1 [cited 2019

2012. p. 27-42.

[81] Salmawati S, Sasaki K,

Assess. 2019 Sep 14;191(9):563.

1;19(17-18):1982-1993.

[83] Sasaki K, Susanto V,

Sep 20];131(8\_9):503-8.

s12182-019-0340-8

31;42(1):21-32.

[86] Serrano E, Rus G,

[84] Ajayi T, Gomes JS, Bera A. A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches. Pet Sci [Internet]. 2019 Jul 8 [cited 2019 Sep 19];1-36. Available from: http://link.springer.com/10.1007/

[85] Ansah EO, Nguele R, Sugai Y, Sasaki K. Predicting the antagonistic effect between albite-anorthite synergy and anhydrite on chemical enhanced oil recovery: effect of inorganic ions and scaling. J Dispers Sci Technol. 2020 Dec

García-Martínez J. Nanotechnology for sustainable energy. Vol. 13, Renewable and Sustainable Energy Reviews. Pergamon; 2009. p. 2373-2384.

[82] Yousefi-Sahzabi A, Sasaki K, Yousefi H, Pirasteh S, Sugai Y. GIS aided prediction of CO2 emission dispersion from geothermal electricity production. J Clean Prod. 2011 Nov

asphaltene precipitation. Energy and Fuels. 2004 Jul;18(4):1038-1048.

*Nanocomposite and Nanofluids: Towards a Sustainable Carbon Capture, Utilization, and Storage DOI: http://dx.doi.org/10.5772/intechopen.95838*

asphaltene precipitation. Energy and Fuels. 2004 Jul;18(4):1038-1048.

*Advances in Microfluidics and Nanofluids*

recovery: a review. J Pet Explor Prod Technol. 2015 Sep;5(3):255-268.

overview. Oil Gas Sci Technol.

[66] Ansah EO, Sugai Y, Nguele R, Sasaki K. Integrated microbial enhanced oil recovery (MEOR) simulation: Main influencing parameters and uncertainty

assessment. J Pet Sci Eng. 2018

[67] Purwasena IA, Astuti DI, Syukron M, Amaniyah M, Sugai Y. Stability test of biosurfactant produced by Bacillus licheniformis DS1 using experimental design and its application for MEOR. J Pet Sci Eng. 2019 Dec 1;183.

[68] Ansah EO, Vo Thanh H, Sugai Y, Nguele R, Sasaki K. Microbe-induced fluid viscosity variation: field-scale simulation, sensitivity and geological uncertainty. J Pet Explor Prod Technol.

Olafuyi OA, Onyekonwu MO. Enhanced Oil Recovery Using Nanoparticles. In: SPE Saudi Arabia Section Technical Symposium and Exhibition. Society of

[70] Hendraningrat L, Li S, Torsæter O. A coreflood investigation of nanofluid enhanced oil recovery. J Pet Sci Eng.

[71] Li S, Hendraningrat L, Torsaeter O. Improved Oil Recovery by Hydrophilic Silica Nanoparticles Suspension: 2-Phase Flow Experimental Studies. In: International Petroleum Technology Conference. International Petroleum Technology Conference; 2013.

Lopera S, Cortés FB, Ruiz MA. Wettability

Alteration of Sandstone Cores by Alumina-Based Nanofluids. Energy & Fuels. 2013 Jul;27(7):3659-3665.

2020 Jun 1;10(5):1983-2003.

Petroleum Engineers; 2012.

2013 Nov;111:128-138.

[72] Giraldo J, Benjumea P,

[69] Ogolo NA,

2008;63(1):9-19.

Dec;171:784-793.

[65] Thomas S. Enhanced oil recovery-an

[73] Kothari N, Raina B, Chandak KB, Iyer V, Mahajan HP. Application Of Ferrofluids For Enhanced Surfactant Flooding In IOR. In: SPE EUROPEC/ EAGE Annual Conference and Exhibition. Society of Petroleum

[75] Haroun MR, Alhassan S, Ansari AA, Al Kindy NAM, Abou Sayed N, Abdul Kareem BA, et al. Smart Nano-EOR Process for Abu Dhabi Carbonate Reservoirs. In: Abu Dhabi International Petroleum Conference and Exhibition. Society of Petroleum Engineers; 2012.

[76] Donaldson EC, Tiab DECD, Donaldson EC. Petrophysics: Theory and Practice of Measuring Reservoir Rock and Fluid Transport Properties. 2nd ed. Book. Gulf Professional Pub./

[77] Tola S, Sasaki K, Sugai Y. Wettability alteration of sandstone with zinc oxide nano-particles. In: 23rd Formation Evaluation Symposium of Japan 2017.

Acuna HM, Cortes F, Patino JE, Cespedes Chavarro C, et al. Application and evaluation of a nanofluid containing nanoparticles for asphaltenes inhibition

Elsevier; 2004. 898 p.

[78] Romero Z, Disney R,

in well CPSXL4. In: OTC Brasil. Offshore Technology Conference; 2013.

[79] Ibrahim HH, Idem RO. Interrelationships between asphaltene precipitation inhibitor

effectiveness, asphaltenes characteristics, and precipitation behavior during n-heptane (light paraffin hydrocarbon)-induced

Engineers; 2010.

Engineers; 2015.

p. 1-13.

2017.

[74] Tarek M, El-Banbi AH. Comprehensive Investigation of Effects of Nano-Fluid Mixtures to Enhance Oil Recovery. In: SPE North Africa Technical Conference and Exhibition. Society of Petroleum

**152**

[80] Goual L. Petroleum Asphaltenes. In: Manar El-Sayed Abdul-Raouf, editor. Crude Oil Emulsions- Composition Stability and Characterization. InTech; 2012. p. 27-42.

[81] Salmawati S, Sasaki K, Sugai Y, Yousefi-Sahzabi A. Estimating a baseline of soil CO2 flux at CO2 geological storage sites. Environ Monit Assess. 2019 Sep 14;191(9):563.

[82] Yousefi-Sahzabi A, Sasaki K, Yousefi H, Pirasteh S, Sugai Y. GIS aided prediction of CO2 emission dispersion from geothermal electricity production. J Clean Prod. 2011 Nov 1;19(17-18):1982-1993.

[83] Sasaki K, Susanto V, Anggara F, Yousefi-Sahzabi A, Sugai Y, Kawamura T, Et Al. Few Considerations on Problems of CO2 Geological Storage with Carbon Circulation and Proposal of An Integrated Regional Energy System considering Low Carbon Society. J MMIJ. 2015 Aug 1 [cited 2019 Sep 20];131(8\_9):503-8.

[84] Ajayi T, Gomes JS, Bera A. A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches. Pet Sci [Internet]. 2019 Jul 8 [cited 2019 Sep 19];1-36. Available from: http://link.springer.com/10.1007/ s12182-019-0340-8

[85] Ansah EO, Nguele R, Sugai Y, Sasaki K. Predicting the antagonistic effect between albite-anorthite synergy and anhydrite on chemical enhanced oil recovery: effect of inorganic ions and scaling. J Dispers Sci Technol. 2020 Dec 31;42(1):21-32.
