Dynamic Viscosity of Indium Oxide-Ethylene Glycol (In₂O₃-EG) Nanofluids: An Experimental Investigation

Abstract: Nanofluids, which are suspensions of nanoparticles, are interesting engineering materials, which might find numerous applications in industry. Unfortunately, there is no coherent theoretical model describing viscosity of nanofluids and further experimental and theoretical studies of this issue should be performed. This paper makes a contribution to this field. Dynamic viscosity of ethylene glycol based nanofluids containing indium oxide nanoparticles was measured in shear rate range from 10 s −1 to 1000 s −1 a… Show more

“…One of these is the work of Fal et al [21] in which they found an increase in the electrical conductivity of these nanofluids with both concentration and temperature. The maximum increase in electrical conductivity of In 2 O 3 -EG nanofluids, 27 300% was detected for a volume fraction of 0.0081 at 333.15 K. Żyła et al [22] presented the results of an experimental study of the dynamic viscosity of indium oxide nanofluids in ethylene glycol and found that these materials exhibit Newtonian character for each nanoparticle fraction tested. They presented in their results that viscosity increases with nanoparticle fraction, and showed that temperature has a strong influence on the viscosity of these materials.…”

Surface Tension of Ethylene Glycol-Based Nanofluids Containing Three Types of Oxides: Zinc Oxide (ZnO), Magnesium Oxide (MgO) and Indium Oxide (In$$_2$$O$$_3$$)

“…One of these is the work of Fal et al [21] in which they found an increase in the electrical conductivity of these nanofluids with both concentration and temperature. The maximum increase in electrical conductivity of In 2 O 3 -EG nanofluids, 27 300% was detected for a volume fraction of 0.0081 at 333.15 K. Żyła et al [22] presented the results of an experimental study of the dynamic viscosity of indium oxide nanofluids in ethylene glycol and found that these materials exhibit Newtonian character for each nanoparticle fraction tested. They presented in their results that viscosity increases with nanoparticle fraction, and showed that temperature has a strong influence on the viscosity of these materials.…”

Surface Tension of Ethylene Glycol-Based Nanofluids Containing Three Types of Oxides: Zinc Oxide (ZnO), Magnesium Oxide (MgO) and Indium Oxide (In$$_2$$O$$_3$$)

Development of an artificial neural network for the prediction of relative viscosity of ethylene glycol based nanofluids

Properties essential for large-scale applications of nanofluids