Darcy-Forchheimer nanofluidic flow manifested with Cattaneo-Christov theory of heat and mass flux over non-linearly stretching surface

doi:10.1371/journal.pone.0221302

Fig 1.

Physical model and coordinate system.

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Fig 2.

H-Curves.

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Table 1.

Convergence.

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Fig 3.

Variation in velocity field for incremental values of λ.

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Fig 4.

Variation in velocity field for incremental values of F_r.

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Fig 5.

Variation in velocity field for incremental values of k₁.

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Fig 6.

Variation in temperature field for incremental values of k₁.

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Fig 7.

Variation in velocity field for incremental values of γ₁.

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Fig 8.

Variation in temperature field for incremental values of M.

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Fig 9.

Variation in temperature field for incremental values of Nt.

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Fig 10.

Variation in temperature field for incremental values of Nb.

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Fig 11.

Variation in concentration of nanoparticles for incremental values of γ₂.

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Fig 12.

Variation in concentration of nanoparticles for incremental values of Nt.

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Fig 13.

Variation in concentration of nanoparticles for incremental values of Pr.

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Table 2.

Numerical results/data of skin-friction for both linear and non-linear cases.

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Table 3.

Numerical results/data of local Nusselt and local Sherwood for both non-linear (n = 1.2) and linear (n = 1) cases at Pr = 1, k₁ = 0.2.

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Table 4.

Comparison of C_f results with Rasool et al. [37].

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Table 5.

Comparison/validation of results with Rasool et al. [37] setting γ₁ = γ₂ = 0 = k₁, n = 1.2.

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Table 6.

Correlation of skin-friction (wall-drag).

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Table 7.

Correlation of heat and mass flux.

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