Physics:Nanofluid
A nanofluid is a fluid containing nanometer-sized particles, called nanoparticles. These fluids are engineered colloidal suspensions of nanoparticles in a base fluid.[1][2] The nanoparticles used in nanofluids are typically made of metals, oxides, carbides, or carbon nanotubes. Common base fluids include water, ethylene glycol[3] and oil.
Nanofluids have novel properties that make them potentially useful in many applications in heat transfer,[4] including microelectronics, fuel cells, pharmaceutical processes, and hybrid-powered engines,[5] engine cooling/vehicle thermal management, domestic refrigerator, chiller, heat exchanger, in grinding, machining and in boiler flue gas temperature reduction. They exhibit enhanced thermal conductivity and the convective heat transfer coefficient compared to the base fluid.[6] Knowledge of the rheological behaviour of nanofluids is found to be critical in deciding their suitability for convective heat transfer applications.[7][8] Nanofluids also have special acoustical properties and in ultrasonic fields display additional shear-wave reconversion of an incident compressional wave; the effect becomes more pronounced as concentration increases.[9]
In analysis such as computational fluid dynamics (CFD), nanofluids can be assumed to be single phase fluids;[10][11] however, almost all new academic papers use a two-phase assumption. Classical theory of single phase fluids can be applied, where physical properties of nanofluid is taken as a function of properties of both constituents and their concentrations.[12] An alternative approach simulates nanofluids using a two-component model.[13]
The spreading of a nanofluid droplet is enhanced by the solid-like ordering structure of nanoparticles assembled near the contact line by diffusion, which gives rise to a structural disjoining pressure in the vicinity of the contact line.[14] However, such enhancement is not observed for small droplets with diameter of nanometer scale, because the wetting time scale is much smaller than the diffusion time scale.[15]
Synthesis
Nanofluids are produced by several techniques:
- Direct Evaporation (1 step)
- Gas condensation/dispersion (2 step)
- Chemical vapour condensation (1 step)
- Chemical precipitation (1 step)
- Bio-based (2 step)
Several liquids including water, ethylene glycol, and oils have been used as base fluids. Although stabilization can be a challenge, on-going research indicates that it is possible. Nano-materials used so far in nanofluid synthesis include metallic particles, oxide particles, carbon nanotubes, graphene nano-flakes and ceramic particles.[16][17]
A bio-based, environmentally friendly approach for the covalent functionalization of multi-walled carbon nanotubes (MWCNTs) using clove buds was developed.[18][19] There are no any toxic and hazardous acids which are typically used in common carbon nanomaterial functionalization procedures, employed in this synthesis. The MWCNTs are functionalized in one pot using a free radical grafting reaction. The clove-functionalized MWCNTs are then dispersed in distilled water (DI water), producing a highly stable MWCNT aqueous suspension (MWCNTs Nanofluid).
Smart cooling nanofluids
Realizing the modest thermal conductivity enhancement in conventional nanofluids, a team of researchers at Indira Gandhi Centre for Atomic Research Centre, Kalpakkam developed a new class of magnetically polarizable nanofluids where the thermal conductivity enhancement up to 300% of basefluids is demonstrated. Fatty-acid-capped magnetite nanoparticles of different sizes (3-10 nm) have been synthesized for this purpose. It has been shown that both the thermal and rheological properties of such magnetic nanofluids are tunable by varying the magnetic field strength and orientation with respect to the direction of heat flow.[20][21][22] Such response stimuli fluids are reversibly switchable and have applications in miniature devices such as micro- and nano-electromechanical systems.[23][24] In 2013, Azizian et al. considered the effect of an external magnetic field on the convective heat transfer coefficient of water-based magnetite nanofluid experimentally under laminar flow regime. Up to 300% enhancement obtained at Re=745 and magnetic field gradient of 32.5 mT/mm. The effect of the magnetic field on the pressure drop was not as significant.[25]
Response stimuli nanofluids for sensing applications
Researchers have invented a nanofluid-based ultrasensitive optical sensor that changes its colour on exposure to extremely low concentrations of toxic cations.[26] The sensor is useful in detecting minute traces of cations in industrial and environmental samples. Existing techniques for monitoring cations levels in industrial and environmental samples are expensive, complex and time-consuming. The sensor is designed with a magnetic nanofluid that consists of nano-droplets with magnetic grains suspended in water. At a fixed magnetic field, a light source illuminates the nanofluid where the colour of the nanofluid changes depending on the cation concentration. This color change occurs within a second after exposure to cations, much faster than other existing cation sensing methods.
Such response stimulus nanofluids are also used to detect and image defects in ferromagnetic components. The photonic eye, as it has been called, is based on a magnetically polarizable nano-emulsion that changes colour when it comes into contact with a defective region in a sample. The device might be used to monitor structures such as rail tracks and pipelines.[27][28]
Magnetically responsive photonic crystals nanofluids
Magnetic nanoparticle clusters or magnetic nanobeads with the size 80–150 nanometers form ordered structures along the direction of the external magnetic field with a regular interparticle spacing on the order of hundreds of nanometers resulting in strong diffraction of visible light in suspension.[29][30]
Nanolubricants
Another word used to describe nanoparticle based suspensions is Nanolubricants.[31] They are mainly prepared using oils used for engine and machine lubrication. So far several materials including metals, oxides and allotropes of carbon have been used to formulate nanolubricants. The addition of nanomaterials mainly enhances the thermal conductivity and anti-wear property of base oils. Although MoS2, graphene, Cu based fluids have been studied extensively, the fundamental understanding of underlying mechanisms is still needed.
Molybdenum disulfide (MoS2) and graphene work as third body lubricants, essentially becoming tiny microscopic ball bearings, which reduce the friction between two contacting surfaces.[32][33] This mechanism is beneficial if a sufficient supply of these particles are present at the contact interface. The beneficial effects are diminished as the rubbing mechanism pushes out the third body lubricants. Changing the lubricant, like-wise, will null the effects of the nanolubricants drained with the oil.
Other nanolubricant approaches, such as Magnesium Silicate Hydroxides (MSH) rely on nanoparticle coatings by synthesizing nanomaterials with adhesive and lubricating functionalities. Research into nanolubricant coatings has been conducted in both the academic and industrial spaces.[34][35] Nanoborate additives as well as mechanical model descriptions of diamond-like carbon (DLC) coating formations have been developed by Ali Erdemir at Argonne National Labs.[36] Companies such as TriboTEX provide consumer formulations of synthesized MSH nanomaterial coatings for vehicle engines and industrial applications.[37][32]
Nanofluids in petroleum refining process
Many researches claim that nanoparticles can be used to enhance crude oil recovery.[38] It is evident that development of nanofluids for oil and gas industry has a great practical aspects.
Applications
Nanofluids are primarily used for their enhanced thermal properties as coolants in heat transfer equipment such as heat exchangers, electronic cooling system(such as flat plate) and radiators.[39] Heat transfer over flat plate has been analyzed by many researchers.[40] However, they are also useful for their controlled optical properties.[41][42][43][44] Graphene based nanofluid has been found to enhance Polymerase chain reaction[45] efficiency. Nanofluids in solar collectors is another application where nanofluids are employed for their tunable optical properties.[46][47][48] Nanofluids have also been explored to enhance thermal desalination technologies, by altering thermal conductivity[49] and absorbing sunlight,[50] but surface fouling of the nanofluids poses a major risk to those approaches.[49] Researchers proposed nanofluids for electronics cooling.[51] Nanofluids also can be used in machining.[52]
Thermophysical properties of nanofluids[53]
Thermal conductivity, viscosity, density, specific heat, and surface tension are considered some main thermophysical properties of nanofluids. Various parameters like nanoparticle type, size, and shape, volume concentration, fluid temperature, and nanofluid preparation method have effect on thermophysical properties of nanofluids.[54]
- Viscosity of nanofluids[55]
- Density of nanofluids
- Thermal conductivity of nanofluids[56]
Nanoparticle migration
The early studies indicating anomalous increases in nanofluid thermal properties over those of the base fluid, particularly the heat transfer coefficient, have been largely discredited. One of the main conclusions taken from a study involving over thirty labs throughout the world[57] was that "no anomalous enhancement of thermal conductivity was observed in the limited set of nanofluids tested in this exercise". The COST funded research programme, Nanouptake (COST Action CA15119)[1] was founded with the intention "to develop and foster the use of nanofluids as advanced heat transfer/thermal storage materials to increase the efficiency of heat exchange and storage systems". One of the final outcomes, involving an experimental study in five different labs, concluded that "there are no anomalous or unexplainable effects".[58]
Despite these apparently conclusive experimental investigations theoretical papers continue to follow the claim of anomalous enhancement, see,[59][60][61][62][63][64][65] particularly via Brownian and thermophoretic mechanisms, as suggested by Buongiorno.[2] Brownian diffusion is due to the random drifting of suspended nanoparticles in the base fluid which originates from collisions between the nanoparticles and liquid molecules. Thermophoresis induces nanoparticle migration from warmer to colder regions, again due to collisions with liquid molecules. The mismatch between experimental and theoretical results is explained in Myers et al.[66] In particular it is shown that Brownian motion and thermophoresis effects are too small to have any significant effect: their role is often amplified in theoretical studies due to the use of incorrect parameter values. Experimental validation of the assertions of [66] are provided in Alkasmoul et al.[67] Brownian diffusion as a cause for enhanced heat transfer is dismissed in the discussion of the use of nanofluids in solar collectors.
See also
- Argonne National Laboratory
- Flow battery
- Fluid dynamics
- Heat transfer
- Nanophase material
- Surface-area-to-volume ratio
- Surfactant
- Therminol
References
- ↑ Taylor, R.A. (2013). "Small particles, big impacts: A review of the diverse applications of nanofluids". Journal of Applied Physics 113 (1): 011301–011301–19. doi:10.1063/1.4754271. Bibcode: 2013JAP...113a1301T. http://jap.aip.org/resource/1/japiau/v113/i1/p011301_s1?bypassSSO=1.
- ↑ 2.0 2.1 Buongiorno, J. (March 2006). "Convective Transport in Nanofluids". Journal of Heat Transfer 128 (3): 240–250. doi:10.1115/1.2150834. http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JHTRAO000128000003000240000001&idtype=cvips&gifs=yes&ref=no. Retrieved 27 March 2010.
- ↑ "Argonne Transportation Technology R&D Center". http://www.transportation.anl.gov/materials/nanofluids.html.
- ↑ Minkowycz, W., et al., Nanoparticle Heat Transfer and Fluid Flow, CRC Press, Taylor & Francis, 2013
- ↑ Das, Sarit K.; Stephen U. S. Choi; Wenhua Yu; T. Pradeep (2007). Nanofluids: Science and Technology. John Wiley & Sons. pp. 397. http://www3.interscience.wiley.com/cgi-bin/bookhome/114200126?CRETRY=1&SRETRY=0. Retrieved 27 March 2010.
- ↑ Kakaç, Sadik; Anchasa Pramuanjaroenkij (2009). "Review of convective heat transfer enhancement with nanofluids". International Journal of Heat and Mass Transfer 52 (13–14): 3187–3196. doi:10.1016/j.ijheatmasstransfer.2009.02.006.
- ↑ S. Witharana, H. Chen, Y. Ding; Stability of nanofluids in quiescent and shear flow fields, Nanoscale Research Letters 2011, 6:231 http://www.nanoscalereslett.com/content/6/1/231/
- ↑ Chen, H.Expression error: Unrecognized word "etal". (2009). "Predicting thermal conductivity of liquid suspensions of nanoparticles (nanofluids) based on Rheology". Particuology 7 (2): 151–157. doi:10.1016/j.partic.2009.01.005.
- ↑ Forrester, D. M. (2016). "Experimental verification of nanofluid shear-wave reconversion in ultrasonic fields". Nanoscale 8 (10): 5497–5506. doi:10.1039/C5NR07396K. PMID 26763173. Bibcode: 2016Nanos...8.5497F.
- ↑ Sreekumar, S.; Shah, N.; Mondol, J.; Hewitt, N.; Chakrabarti, S. (June 2022). "Numerical Investigation and Feasibility Study on MXene/Water Nanofluid Based Photovoltaic/thermal System". Cleaner Energy Systems 103: 504–515. doi:10.1016/j.cles.2022.100010.
- ↑ Alizadeh, M. R.; Dehghan, A. A. (2014-02-01). "Conjugate Natural Convection of Nanofluids in an Enclosure with a Volumetric Heat Source" (in en). Arabian Journal for Science and Engineering 39 (2): 1195–1207. doi:10.1007/s13369-013-0658-2. ISSN 2191-4281.
- ↑ Maiga, Sidi El Becaye; Palm, S.J.; Nguyen, C.T.; Roy, G; Galanis, N (3 June 2005). "Heat transfer enhancement by using nanofluids in forced convection flows". International Journal of Heat and Fluid Flow 26 (4): 530–546. doi:10.1016/j.ijheatfluidflow.2005.02.004.
- ↑ Kuznetsov, A.V.; Nield, D.A. (2010). "Natural convective boundary-layer flow of a nanofluid past a vertical plate". International Journal of Thermal Sciences 49 (2): 243–247. doi:10.1016/j.ijthermalsci.2009.07.015.
- ↑ Wasan, Darsh T.; Nikolov, Alex D. (May 2003). "Spreading of nanofluids on solids". Nature 423 (6936): 156–159. doi:10.1038/nature01591. PMID 12736681. Bibcode: 2003Natur.423..156W.
- ↑ Lu, Gui; Hu, Han; Duan, Yuanyuan; Sun, Ying (2013). "Wetting kinetics of water nano-droplet containing non-surfactant nanoparticles: A molecular dynamics study". Appl. Phys. Lett. 103 (25): 253104. doi:10.1063/1.4837717. Bibcode: 2013ApPhL.103y3104L.
- ↑ Kumar Das, Sarit (December 2006). "Heat Transfer in Nanofluids—A Review". Heat Transfer Engineering 27 (10): 3–19. doi:10.1080/01457630600904593. Bibcode: 2006HTrEn..27....3D.
- ↑ Nor Azwadi, Che Sidik (2014). "A review on preparation methods and challenges of nanofluids". International Communications in Heat and Mass Transfer 54: 115–125. doi:10.1016/j.icheatmasstransfer.2014.03.002.
- ↑ Sadri, R (15 October 2017). "A bio-based, facile approach for the preparation of covalently functionalized carbon nanotubes aqueous suspensions and their potential as heat transfer fluids". Journal of Colloid and Interface Science 504: 115–123. doi:10.1016/j.jcis.2017.03.051. PMID 28531649. Bibcode: 2017JCIS..504..115S.
- ↑ Hosseini, M (February 22, 2017). "Experimental Study on Heat Transfer and Thermo-Physical Properties of Covalently Functionalized Carbon Nanotubes Nanofluids in an Annular Heat Exchanger: A Green and Novel Synthesis". Energy & Fuels 31 (5): 5635–5644. doi:10.1021/acs.energyfuels.6b02928.
- ↑ Heysiattalab, S.; Malvandi, A.; Ganji, D. D. (2016-07-01). "Anisotropic behavior of magnetic nanofluids (MNFs) at filmwise condensation over a vertical plate in presence of a uniform variable-directional magnetic field". Journal of Molecular Liquids 219: 875–882. doi:10.1016/j.molliq.2016.04.004.
- ↑ Malvandi, Amir (2016-06-01). "Anisotropic behavior of magnetic nanofluids (MNFs) at film boiling over a vertical cylinder in the presence of a uniform variable-directional magnetic field". Powder Technology 294: 307–314. doi:10.1016/j.powtec.2016.02.037.
- ↑ Malvandi, Amir (2016-05-15). "Film boiling of magnetic nanofluids (MNFs) over a vertical plate in presence of a uniform variable-directional magnetic field". Journal of Magnetism and Magnetic Materials 406: 95–102. doi:10.1016/j.jmmm.2016.01.008. Bibcode: 2016JMMM..406...95M.
- ↑ J. Philip, Shima.P.D. & B. Raj (2006). "Nanofluid with tunable thermal properties". Applied Physics Letters 92 (4): 043108. doi:10.1063/1.2838304. Bibcode: 2008ApPhL..92d3108P.
- ↑ Shima P.D.and J. Philip (2011). "Tuning of Thermal Conductivity and Rheology of Nanofluids using an External Stimulus". J. Phys. Chem. C 115 (41): 20097–20104. doi:10.1021/jp204827q.
- ↑ Azizian, R.; Doroodchi, E.; McKrell, T.; Buongiorno, J.; Hu, L.W.; Moghtaderi, B. (2014). "Effect of magnetic field on laminar convective heat transfer of magnetite nanofluids". Int. J. Heat Mass 68: 94–109. doi:10.1016/j.ijheatmasstransfer.2013.09.011.
- ↑ Mahendran, V. (2013). "Spectral Response of MagneticNanofluid to Toxic Cations". Appl. Phys. Lett. 102 (16): 163109. doi:10.1063/1.4802899. Bibcode: 2013ApPhL.102p3109M.
- ↑ Mahendran, V. (2012). "Nanofluid based opticalsensor for rapid visual inspection of defects in ferromagnetic materials". Appl. Phys. Lett. 100 (7): 073104. doi:10.1063/1.3684969. Bibcode: 2012ApPhL.100g3104M.
- ↑ "Nanofluid sensor images defects". nanotechweb.org. http://nanotechweb.org/cws/article/tech/48783.
- ↑ He, Le; Wang, Mingsheng; Ge, Jianping; Yin, Yadong (18 September 2012). "Magnetic Assembly Route to Colloidal Responsive Photonic Nanostructures". Accounts of Chemical Research 45 (9): 1431–1440. doi:10.1021/ar200276t. PMID 22578015. https://escholarship.org/uc/item/1274g7zx.
- ↑ http://nanos-sci.com/technology.html Properties and use of magnetic nanoparticle clusters (magnetic nanobeads)
- ↑ Rasheed, A.K.; Khalid, M.; Javeed, A.; Rashmi, W.; Gupta, T.C.S.M.; Chan, A. (November 2016). "Heat transfer and tribological performance of graphene nanolubricant in an internal combustion engine". Tribology International 103: 504–515. doi:10.1016/j.triboint.2016.08.007.
- ↑ 32.0 32.1 Anis M, AlTaher G, Sarhan W, Elsemary M. Nanovate : Commercializing Disruptive Nanotechnologies.
- ↑ Fox-Rabinovich GS, Totten GE. Self-Organization during Friction : Advanced Surface-Engineered Materials and Systems Design. CRC/Taylor & Francis; 2007.
- ↑ Rudenko P (Washington SU, Chang Q, Erdemir A (Argonne NL. Effect of Magnesium Hydrosillicate on Rolling Element Bearings. In: STLE 2014 Annual Meeting. ; 2014.
- ↑ Chang Q, Rudenko P (Washington SU, Miller D, et al. Diamond like Nanocomposite Boundary Films from Synthetic Magnesium Silicon Hydroxide (MSH) Additives.; 2014.
- ↑ Erdemir A, Ramirez G, Eryilmaz OL, et al. Carbon-based tribofilms from lubricating oils. Nature. 2016;536(7614):67-71. doi:10.1038/nature18948.
- ↑ TriboTEX. http://tribotex.com/. Accessed September 30, 2017.
- ↑ Suleimanov, B.A.; Ismailov, F.S.; Veliyev, E.F. (2011-08-01). "Nanofluid for enhanced oil recovery" (in en). Journal of Petroleum Science and Engineering 78 (2): 431–437. doi:10.1016/j.petrol.2011.06.014. ISSN 0920-4105. Bibcode: 2011JPSE...78..431S. https://figshare.com/articles/journal_contribution/11346632.
- ↑ "Advances in Mechanical Engineering". hindawi.com. http://www.hindawi.com/journals/ame/2010/519659/.
- ↑ http://nanofluid.ir
- ↑ Phelan, Patrick; Otanicar, Todd; Taylor, Robert; Tyagi, Himanshu (2013-05-17). "Trends and Opportunities in Direct-Absorption Solar Thermal Collectors". Journal of Thermal Science and Engineering Applications 5 (2): 021003. doi:10.1115/1.4023930. ISSN 1948-5085.
- ↑ Hewakuruppu, Yasitha L.; Dombrovsky, Leonid A.; Chen, Chuyang; Timchenko, Victoria; Jiang, Xuchuan; Baek, Sung; Taylor, Robert A. (2013-08-20). "Plasmonic "pump–probe" method to study semi-transparent nanofluids". Applied Optics 52 (24): 6041–50. doi:10.1364/ao.52.006041. PMID 24085009. Bibcode: 2013ApOpt..52.6041H.
- ↑ Lv, Wei; Phelan, Patrick E.; Swaminathan, Rajasekaran; Otanicar, Todd P.; Taylor, Robert A. (2012-11-21). "Multifunctional Core-Shell Nanoparticle Suspensions for Efficient Absorption". Journal of Solar Energy Engineering 135 (2): 021004. doi:10.1115/1.4007845. ISSN 0199-6231.
- ↑ Otanicar, Todd P.; Phelan, Patrick E.; Taylor, Robert A.; Tyagi, Himanshu (2011-03-22). "Spatially Varying Extinction Coefficient for Direct Absorption Solar Thermal Collector Optimization". Journal of Solar Energy Engineering 133 (2): 024501. doi:10.1115/1.4003679. ISSN 0199-6231.
- ↑ "Enhancing the efficiency of polymerase chain reaction using graphene nanoflakes - Abstract - Nanotechnology - IOPscience". iop.org. http://iopscience.iop.org/0957-4484/23/45/455106.
- ↑ Sreekumar, S.; Shah, N.; Mondol, J.; Hewitt, N.; Chakrabarti, S. (February 2022). "Broadband absorbing mono, blended and hybrid nanofluids for direct absorption solar collector: A comprehensive review". Nano Futures 103 (2): 504–515. doi:10.1088/2399-1984/ac57f7. Bibcode: 2022NanoF...6b2002S. https://pure.ulster.ac.uk/ws/files/99749348/SREEKUMAR_et_al_2022_Nano_Futures_10.1088_2399_1984_ac57f7.pdf.
- ↑ Taylor, Robert A (2011). "Nanofluid optical property characterization: towards efficient direct absorption solar collectors". Nanoscale Research Letters 6 (1): 225. doi:10.1186/1556-276X-6-225. PMID 21711750. Bibcode: 2011NRL.....6..225T.
- ↑ Taylor, Robert A (October 2012). "Nanofluid-based optical filter optimization for PV/T systems". Light: Science & Applications 1 (10): e34. doi:10.1038/lsa.2012.34. Bibcode: 2012LSA.....1E..34T.
- ↑ 49.0 49.1 Parmar, Harsharaj B.; Fattahi Juybari, Hamid; Yogi, Yashwant S.; Nejati, Sina; Jacob, Ryan M.; Menon, Prashant S.; Warsinger, David M. (2021). "Nanofluids improve energy efficiency of membrane distillation". Nano Energy (Elsevier BV) 88: 106235. doi:10.1016/j.nanoen.2021.106235. ISSN 2211-2855.
- ↑ Zhang, Yong; Liu, Lie; Li, Kuiling; Hou, Deyin; Wang, Jun (2018). "Enhancement of energy utilization using nanofluid in solar powered membrane distillation". Chemosphere (Elsevier BV) 212: 554–562. doi:10.1016/j.chemosphere.2018.08.114. ISSN 0045-6535. PMID 30165282. Bibcode: 2018Chmsp.212..554Z.
- ↑ Khaleduzzaman, S. S.; Rahman, Saidur; Selvaraj, Jeyraj; Mahbubul, I. M.; Sohel, M. R.; Shahrul, I. M. (2014). "Nanofluids for Thermal Performance Improvement in Cooling of Electronic Device" (in en). Advanced Materials Research 832: 218–223. doi:10.4028/www.scientific.net/AMR.832.218. ISSN 1662-8985. https://www.scientific.net/AMR.832.218.
- ↑ Vasu, V.; Kumar, K. Manoj (2011-12-01). "Analysis of Nanofluids as Cutting Fluid in Grinding EN-31 Steel" (in en). Nano-Micro Letters 3 (4): 209–214. doi:10.1007/BF03353674. ISSN 2150-5551.
- ↑ Mahbubul, I. M. (2019-01-01), Mahbubul, I. M., ed., "4 - Thermophysical Properties of Nanofluids" (in en), Preparation, Characterization, Properties and Application of Nanofluid, Micro and Nano Technologies (William Andrew Publishing): pp. 113–196, ISBN 978-0-12-813245-6, https://www.sciencedirect.com/science/article/pii/B9780128132456000046, retrieved 2022-09-18
- ↑ Mahbubul, I. M. (2019-01-01), Mahbubul, I. M., ed., "4 - Thermophysical Properties of Nanofluids" (in en), Preparation, Characterization, Properties and Application of Nanofluid, Micro and Nano Technologies (William Andrew Publishing): pp. 113–196, ISBN 978-0-12-813245-6, https://www.sciencedirect.com/science/article/pii/B9780128132456000046, retrieved 2022-09-18
- ↑ Mahbubul, I. M.; Saidur, R.; Amalina, M. A. (2012-01-31). "Latest developments on the viscosity of nanofluids" (in en). International Journal of Heat and Mass Transfer 55 (4): 874–885. doi:10.1016/j.ijheatmasstransfer.2011.10.021. ISSN 0017-9310. https://www.sciencedirect.com/science/article/pii/S0017931011005904.
- ↑ "Thermal Conductivity of Nanofluids" (in en). https://encyclopedia.pub/entry/9666.
- ↑ Buongiorno, Jacopo; Venerus, David C.; Prabhat, Naveen; McKrell, Thomas; Townsend, Jessica; Christianson, Rebecca; Tolmachev, Yuriy V.; Keblinski, Pawel et al. (2009-11-01). "A benchmark study on the thermal conductivity of nanofluids". Journal of Applied Physics 106 (9): 094312–094312–14. doi:10.1063/1.3245330. ISSN 0021-8979. Bibcode: 2009JAP...106i4312B.
- ↑ Buschmann, M. H.; Azizian, R.; Kempe, T.; Juliá, J. E.; Martínez-Cuenca, R.; Sundén, B.; Wu, Z.; Seppälä, A. et al. (2018-07-01). "Correct interpretation of nanofluid convective heat transfer". International Journal of Thermal Sciences 129: 504–531. doi:10.1016/j.ijthermalsci.2017.11.003. ISSN 1290-0729.
- ↑ Bahiraei, Mehdi (2015-09-01). "Effect of particle migration on flow and heat transfer characteristics of magnetic nanoparticle suspensions". Journal of Molecular Liquids 209: 531–538. doi:10.1016/j.molliq.2015.06.030.
- ↑ Malvandi, A.; Ghasemi, Amirmahdi; Ganji, D. D. (2016-11-01). "Thermal performance analysis of hydromagnetic Al2O3-water nanofluid flows inside a concentric microannulus considering nanoparticle migration and asymmetric heating". International Journal of Thermal Sciences 109: 10–22. doi:10.1016/j.ijthermalsci.2016.05.023.
- ↑ Bahiraei, Mehdi (2015-05-01). "Studying nanoparticle distribution in nanofluids considering the effective factors on particle migration and determination of phenomenological constants by Eulerian–Lagrangian simulation". Advanced Powder Technology. Special issue of the 7th World Congress on Particle Technology 26 (3): 802–810. doi:10.1016/j.apt.2015.02.005.
- ↑ Pakravan, Hossein Ali; Yaghoubi, Mahmood (2013-06-01). "Analysis of nanoparticles migration on natural convective heat transfer of nanofluids". International Journal of Thermal Sciences 68: 79–93. doi:10.1016/j.ijthermalsci.2012.12.012.
- ↑ Malvandi, A.; Moshizi, S. A.; Ganji, D. D. (2016-01-01). "Two-component heterogeneous mixed convection of alumina/water nanofluid in microchannels with heat source/sink". Advanced Powder Technology 27 (1): 245–254. doi:10.1016/j.apt.2015.12.009.
- ↑ Malvandi, A.; Ganji, D. D. (2014-10-01). "Brownian motion and thermophoresis effects on slip flow of alumina/water nanofluid inside a circular microchannel in the presence of a magnetic field". International Journal of Thermal Sciences 84: 196–206. doi:10.1016/j.ijthermalsci.2014.05.013.
- ↑ Bahiraei, Mehdi; Abdi, Farshad (2016-10-15). "Development of a model for entropy generation of water-TiO2 nanofluid flow considering nanoparticle migration within a minichannel". Chemometrics and Intelligent Laboratory Systems 157: 16–28. doi:10.1016/j.chemolab.2016.06.012.
- ↑ 66.0 66.1 Myers, Tim G.; Ribera, Helena; Cregan, Vincent (2017-08-01). "Does mathematics contribute to the nanofluid debate?". International Journal of Heat and Mass Transfer 111: 279–288. doi:10.1016/j.ijheatmasstransfer.2017.03.118. ISSN 0017-9310.
- ↑ Alkasmoul, Fahad S.; Al-Asadi, M. T.; Myers, T. G.; Thompson, H. M.; Wilson, M. C. T. (2018-11-01). "A practical evaluation of the performance of Al2O3-water, TiO2-water and CuO-water nanofluids for convective cooling". International Journal of Heat and Mass Transfer 126: 639–651. doi:10.1016/j.ijheatmasstransfer.2018.05.072. ISSN 0017-9310. http://eprints.whiterose.ac.uk/131074/1/Alkasmoul-2018-IJHMT-nanofluids-AAM.pdf.
- ↑ Khashi’ie, N.S., Md Arifin, N., Nazar, R., Hafidzuddin, E.H., Wahi, N. and Pop, I., 2019. A Stability Analysis for Magnetohydrodynamics Stagnation Point Flow with Zero Nanoparticles Flux Condition and Anisotropic Slip. Energies, 12(7), p.1268. https://doi.org/10.3390/en12071268.
External links
- Magnetically responsive photonic crystals nanofluid (video) produced by Nanos scientificae
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Original source: https://en.wikipedia.org/wiki/Nanofluid.
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