Thin Film Flow in MHD Third Grade Fluid on a Vertical Belt with Temperature Dependent Viscosity | PLOS One

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Figure 1.

Geometry of the problem (a) Lift problem and (b) Drainage problem.

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Figure 2.

Comparison of ADM and OHAM methods for lift velocity profile. .

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Figure 2.

Comparison of ADM and OHAM methods for lift velocity profile. .

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Figure 3.

Comparison of ADM and OHAM methods for lift temperature distribution..

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Figure 3.

Comparison of ADM and OHAM methods for lift temperature distribution..

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Figure 4.

Comparison of ADM and OHAM methods for drainage velocity profile..

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Figure 4.

Comparison of ADM and OHAM methods for drainage velocity profile..

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Figure 5.

Comparison of ADM and OHAM methods for drainage temperature distribution..

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Figure 5.

Comparison of ADM and OHAM methods for drainage temperature distribution..

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Figure 6.

Influence of the Brinkman number on the lift velocity profile when _.

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Figure 6.

Influence of the Brinkman number on the lift velocity profile when _.

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Figure 7.

Influence of the Brinkman number on the lift temperature distribution when _.

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Figure 7.

Influence of the Brinkman number on the lift temperature distribution when _.

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Figure 8.

Effect of Stock number on the lift velocity profile. when _.

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Figure 8.

Effect of Stock number on the lift velocity profile. when _.

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Figure 9.

Effect of Stock number on the lift temperature distribution when _.

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Figure 9.

Effect of Stock number on the lift temperature distribution when _.

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Figure 10.

Effect of viscosity parameter on the lift velocity profile. when _.

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Figure 10.

Effect of viscosity parameter on the lift velocity profile. when _.

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Figure 11.

Effect of viscosity parameter on the lift temperature distribution when _.

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Figure 11.

Effect of viscosity parameter on the lift temperature distribution when _.

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Figure 12.

The effect of magnetic force on lift velocity profile when _.

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Figure 12.

The effect of magnetic force on lift velocity profile when _.

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Figure 13.

The effect of magnetic force on lift temperature distribution when _.

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Figure 13.

The effect of magnetic force on lift temperature distribution when _.

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Figure 14.

The effect of Stock number on velocity for drainage problem when _.

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Figure 14.

The effect of Stock number on velocity for drainage problem when _.

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Figure 15.

The effect of Stock number on temperature for drainage problem when _.

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Figure 15.

The effect of Stock number on temperature for drainage problem when _.

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Figure 16.

Drain velocity for various values of viscosity parameter when _.

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Figure 16.

Drain velocity for various values of viscosity parameter when _.

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Figure 17.

Drain temperature distribution for various values of viscosity parameter when _.

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Figure 17.

Drain temperature distribution for various values of viscosity parameter when _.

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Figure 18.

The influence of non-Newtonian parameter on velocity for drainage problem when _.

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Figure 18.

The influence of non-Newtonian parameter on velocity for drainage problem when _.

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Figure 19.

The influence of non-Newtonian parameter on temperature for drainage problem when _.

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Figure 19.

The influence of non-Newtonian parameter on temperature for drainage problem when _.

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Figure 20.

Comparison of the present results with published work [22] when .

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Figure 20.

Comparison of the present results with published work [22] when .

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Table 1.

Numerical results show the comparison of present results with published work [22] when .

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Table 1 — Table 1.

Numerical results show the comparison of present results with published work [22] when .

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