Fluid Flow and Heat Transfer Analysis of a Nanofluid Containing Motile Gyrotactic Micro-Organisms Passing a Nonlinear Stretching Vertical Sheet in the Presence of a Non-Uniform Magnetic Field; Numerical Approach | PLOS One

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Fig 1 — Fig 1.

Flow configuration and coordinate system.

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Fig 2 — Fig 2.

Effects of different parameters on the skin friction coefficient (-f^"(0)), Nusselt number (-θ'(0)) and Sherwood number (-φ'(0)) (a) Present code and (b). Mabood et al. [32].

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Table 1 — Table 1.

Comparison of Nusselt and Sherwood numbers between the results of present study and reported by Khan and Pop [24] at Le = Pr = 10, n = 1, M = Ec = Nr = Rb = Pe = Lb = Ω = 0 and different values for Nt and Nb.

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Table 2 — Table 2.

Comparison of the density number of the motile micro-organisms between the results of present study and reported by Akbar and Khan [54] at n = 1, M = Nb = 1, Ec = 0, Nr = Nt = Gr = 0.5, Lb = Le = 2, Rb = 0.3 and different values for Ω and Pe.

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Fig 3 — Fig 3.

Effects of M and n on the dimensionless velocity.

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Fig 4 — Fig 4.

Effects of Gr/Re² and Ec on the dimensionless velocity.

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Fig 5 — Fig 5.

Effects of Nr and Rb on the dimensionless velocity.

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Fig 6 — Fig 6.

Effects of M and n on the dimensionless temperature.

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Fig 7 — Fig 7.

Effects of Gr/Re² on the dimensionless temperature.

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Fig 8 — Fig 8.

Effects of Ec and Gr/Re² on the dimensionless temperature.

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Fig 9 — Fig 9.

Effects of Nb and Nt on the dimensionless temperature.

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Fig 10 — Fig 10.

Effects of Nr and Rb on the dimensionless temperature.

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Fig 11 — Fig 11.

Effects of M and n on the nanoparticles concentration.

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Fig 12 — Fig 12.

Effects of Gr/Re² and Le on the nanoparticles concentration.

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Fig 13 — Fig 13.

Effects of Nb on the nanoparticles concentration.

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Fig 14 — Fig 14.

Effects of Nt on the nanoparticles concentration.

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Fig 15 — Fig 15.

Effects of M and n on the density of motile microorganisms.

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Fig 16 — Fig 16.

Effects of Gr/Re² on the density of motile microorganisms.

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Fig 17 — Fig 17.

Effects of Ω and Lb on the density of motile microorganisms.

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Fig 18 — Fig 18.

Effects of Ec and Pe on the density of motile microorganisms.

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Fig 19 — Fig 19.

Effects of M, n, Gr/Re² and Rb on the skin friction coefficient.

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Fig 20 — Fig 20.

Effects of Nr, Pe, Ω and Nb on the skin friction coefficient.

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Fig 21 — Fig 21.

Effects of M, n, Gr/Re² and Le on the Nusselt number.

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Fig 22 — Fig 22.

Effects of Ec, Nb and Nt on the Nusselt number.

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Fig 23 — Fig 23.

Effects of Nr, Rb and Lb on the Nusselt number.

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Fig 24 — Fig 24.

Effects of M, n, Gr/Re² and Le on the Sherwood number.

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Fig 25 — Fig 25.

Effects of Rb, Nt, Nb and Nr on the Sherwood number.

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Fig 26 — Fig 26.

Effects of M, n, Lb and Rb on the density number of the motile micro-organisms.

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Fig 27 — Fig 27.

Effects of Ec, Gr/Re², Pe and Ω on the density number of the motile micro-organisms.

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