Numerical Approach toward Ternary Hybrid Nanofluid Flow Using Variable Diffusion and Non-Fourier’s Concept

Algehyne, Ebrahem A.; Alrihieli, Haifaa F.; Bilal, Muhammad; Saeed, Anwar; Weera, Wajaree

doi:10.1021/acsomega.2c03634

“…Meanwhile, Shah et al 21 studied the flow behaviour of ternary nanofluid in which the base fluid was assumed to be a second grade nanofluid. Aleghyne et al 22 dealt with the investigation of variable diffusion on the thermal features of ternary nanofluid. Ramzan et al 23 suspended three nanoparticles into the partially ionised kerosene to use it as a coolant to reduce the heat present on the rotating surface.…”

mentioning

confidence: 99%

Analysis of the Thomson and Troian velocity slip for the flow of ternary nanofluid past a stretching sheet

Li

¹

,

Puneeth

²

,

Saeed

³

et al. 2023

Sci Rep

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In this article, the flow of ternary nanofluid is analysed past a stretching sheet subjected to Thomson and Troian slip condition along with the temperature jump. The ternary nanofluid is formed by suspending three different types of nanoparticles namely $$\text{TiO}_{2}, \text{Cu}$$ TiO 2 , Cu and $$\text{Ag}$$ Ag into water which acts as a base fluid and leads to the motion of nanoparticles. The high thermal conductivity and chemical stability of silver was the main cause for its suspension as the third nanoparticle into the hybrid nanofluid $$\text{Cu-TiO}_{2}/\text{H}_{2} \text{O}$$ Cu-TiO 2 / H 2 O . Thus, forming the ternary nanofluid $$\text{Ag-Cu-TiO}_{2}/\text{H}_{2} \text{O}$$ Ag-Cu-TiO 2 / H 2 O . The sheet is assumed to be vertically stretching where the gravitational force will have its impact in the form of free convection. Furthermore, the presence of radiation and heat source/sink is assumed so that the energy equation thus formed will be similar to most of the real life applications. The assumption mentioned here leads to the mathematical model framed using partial differential equations (PDE) which are further transformed to ordinary differential equations (ODE) using suitable similarity transformations. Thus, obtained system of equations is solved by incorporating the RKF-45 numerical technique. The results indicated that the increase in the suspension of silver nanoparticles enhanced the temperature and due to density, the velocity of the flow is reduced. The slip in the velocity decreased the flow speed while the temperature of the nanofluid was observed to be increasing.

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“…Mahabaleshwar 33 considered linear stretching sheet problem in porous domain with suction. Recent works on the flow of hybrid nanofluids over differenr geometries has been repoted in [34][35][36][37][38][39][40][41][42][43][44][45] .…”

Section: List Of Symbols Gmentioning

confidence: 99%

Casson nanoliquid film flow over an unsteady moving surface with time-varying stretching velocity

Vanitha

¹

,

Shobha

²

,

Mallikarjun

³

et al. 2023

Sci Rep

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Present study explains about unsteady Casson nanoliquid film flow over a surface moving with velocity $$U_w=\lambda x/t$$ U w = λ x / t . The governing momentum equation is reduced to ODE by using corresponding similarity transformation, which is then tackled by employing numerical technique. The problem is analysed for both two-dimensional film flow and axisymmetric film flow. The exact solution is derived which satisfies the governing equation. It is noted that solution exists only for a specified scale of the moving surface parameter $$\lambda$$ λ . ie., $$\lambda \ge -1/2$$ λ ≥ - 1 / 2 for two-dimensional flow and $$\lambda \le -1/4$$ λ ≤ - 1 / 4 for axisymmetric flow. The velocity increases first and reaches the maximum velocity and then decreases to the boundary condition. Streamlines are also analysed for both axisymmetric and two-dimensional flow patterns by considering the stretching ($$\lambda >0$$ λ > 0 ) and shrinking wall conditions ($$\lambda <0$$ λ < 0 ). Study has been made for large values of wall moving parameter $$\lambda$$ λ . The aim of this investigation is to analyse the Casson nanoliquid film flow which finds applications in industries like coating of sheet or wire, laboratories, painting, many more.

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“…where 𝜇 denotes the dynamic viscosity, 𝑘 is the thermal conductivity, nf denotes nanofluid with single type particles, 𝜓 * = 𝜓 1 + 𝜓 2 + 𝜓 3 is the total nanoparticle volume fraction, 𝜇 𝑛𝑓1 and 𝑘 𝑛𝑓1 , 𝜇 𝑛𝑓2 and 𝑘 𝑛𝑓2 , and 𝜇 𝑛𝑓3 and 𝑘 𝑛𝑓3 are, respectively, defined, based on their shapes of spherical [27], cylindrical [29], platelet [31] The thermophysical properties of base fluid (ethylene glycol) and different nanoparticles, and the shape factors of nanoparticles used in this paper are presented in Tables 1 and 2, respectively. The relationship between the thermal conductivity of nanofluids measured at room temperature and the volume concentration of nanoparticles with different nanoparticle shapes is shown in Figure 2.…”

Section: Ternary Hybrid Nanofluid Propertiesmentioning

confidence: 99%

“…Sahoo et al [27] developed an accurate correlation to estimate the maximum deviation of viscosity of a Al 2 O 3 -CuO-TiO 2 /H 2 O ternary hybrid nanofluid. Applications of ternary hybrid nanofluids have been reported by Manjunatha et al [28], Algehyne et al [29], and so on. Further important contributions on ternary hybrid nanofluid models can be found in Refs.…”

Section: Introductionmentioning

confidence: 99%

Fully developed opposing mixed convection of a Jeffery tri‐hybrid nanofluid between two parallel inclined plates subjected to wall‐slip condition

Bibi,

Xu

2023

Z Angew Math Mech

1

0

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We analyze the effect of wall slip on the fully developed reverse mixed convection of Jeffery nanofluids between two inclined parallel plates with uniform wall heat flux conditions. The theory of tri‐hybrid water‐based nanoparticles with unique shapes, namely, cylindrical (copper), spherical (titanium oxide), and platelet (aluminum oxide) for heat transfer enhancement is utilized since it has better heat performance applicable in a dynamic of fuels and coolant in automobiles as compared with regular Newtonian fluid and nanofluid. The equations describing the above transport phenomena are nondimensional through appropriate scale transformations. Analytical solutions for velocity, temperature, and pressure distributions are obtained. Four different flow regimes including no reversal, bottom reversal, top reversal, and on both walls reversal are found for different combinations of buoyancy and pressure. Particularly, we notice that the wall slip significantly affects flow reversal. Furthermore, we notice that Magyari 's conclusion that the results of the homogeneous nanofluid flow model can be recovered from the corresponding Newtonian fluid model has great limitations. Besides, the effect of several physical factors on velocity and temperature distributions and important physical quantities, including skin friction coefficient and Nusselt number, are analyzed and graphically discussed.

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Numerical Approach toward Ternary Hybrid Nanofluid Flow Using Variable Diffusion and Non-Fourier’s Concept

Cited by 45 publications

References 53 publications

Analysis of the Thomson and Troian velocity slip for the flow of ternary nanofluid past a stretching sheet

Analysis of the Thomson and Troian velocity slip for the flow of ternary nanofluid past a stretching sheet

Casson nanoliquid film flow over an unsteady moving surface with time-varying stretching velocity

Fully developed opposing mixed convection of a Jeffery tri‐hybrid nanofluid between two parallel inclined plates subjected to wall‐slip condition

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