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Fig 1.

Geometry of the problem.

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Fig 1 Expand

Table 1.

Thermophysical properties of the nanoparticles and base fluid (water).

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Table 1 Expand

Table 2.

Variation of skin friction coefficient () with different values of ϕ, λ, n and β.

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Table 2 Expand

Fig 2.

Effect of n, ϕ on f′(ξ).

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Fig 2 Expand

Fig 3.

Effect of n, ϕ on g′(ξ).

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Fig 3 Expand

Fig 4.

Effect of λ, ϕ on f′(ξ).

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Fig 4 Expand

Fig 5.

Effect of λ, ϕ on g′(ξ).

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Fig 5 Expand

Fig 6.

Effect of β, ϕ on f′(ξ).

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Fig 6 Expand

Fig 7.

Effect of β, ϕ on g′(ξ).

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Fig 7 Expand

Fig 8.

Effect of n, ϕ on θ(ξ).

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Fig 8 Expand

Fig 9.

Effect of λ, ϕ on θ(ξ).

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Fig 9 Expand

Fig 10.

Effect of β, ϕ on θ(ξ).

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Fig 10 Expand

Fig 11.

Effect of δ, ϕ on θ(ξ).

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Fig 11 Expand

Fig 12.

Effect of n, ϕ on Φ(ξ).

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Fig 12 Expand

Fig 13.

Effect of λ, ϕ on Φ(ξ).

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Fig 13 Expand

Fig 14.

Effect of β, ϕ on Φ(ξ).

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Fig 14 Expand

Fig 15.

Effect of γ, ϕ on Φ(ξ).

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Fig 15 Expand

Fig 16.

Effect of Sc, φ on Φ(ξ).

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Fig 16 Expand

Fig 17.

Effect of λ, β, ϕ on (Rex)1/2Cfx.

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Fig 17 Expand

Fig 18.

Effect of λ, β, ϕ on (Rey)1/2Cfy.

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Fig 18 Expand

Fig 19.

Streamlines for different values of nanoparticles volume fraction ϕ at λ = n = β = 3.

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Fig 19 Expand

Fig 20.

Isotherms for different values of nanoparticles volume fraction ϕ at λ = n = β = 3, δ = γ = 2.

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Fig 20 Expand

Table 3.

Variation of skin friction coefficient () with different values of ϕ, λ, n and β.

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Table 3 Expand

Fig 21.

Effect of ϕ, β, λ on −θ′(0).

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Fig 21 Expand

Fig 22.

Effect of ϕ, γ, Sc on −Φ′(0).

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Fig 22 Expand

Table 4.

Comparison of f″(0) and g″(0) for value of n when other parameters are zero.

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Table 4 Expand