Nanomaterials
 2022
DOI: 10.3390/nano12101745
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Insight into the Dynamics of Fractional Maxwell Nano-Fluids Subject to Entropy Generation, Lorentz Force and Heat Source via Finite Difference Scheme

Muhammad Imran Asjad
1
,
Muhammad Usman
2
,
Arfan Ali
3
et al.

Abstract: In recent times, the loss of useful energy and solutions to those energy challenges have a wide scope in different areas of engineering. This work focuses on entropy analysis for unsteady viscoelastic fluids. The momentum boundary layer and thermal boundary layer are described under the effects of a magnetic field in the absence of an induced magnetic field. The study of a fractional model of Maxwell nanofluid by partial differential equation using Caputo time differential operator can well address the memory … Show more

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A novel definition of the caputo fractional finite difference approach for Maxwell fluid

Zubair,
Zanib,
Asjad
2024
Comp. Appl. Math.
5
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0
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A novel definition of the caputo fractional finite difference approach for Maxwell fluid

Zubair,
Zanib,
Asjad
2024
Comp. Appl. Math.
5
0
0
0
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Thermofluid of Maxwellian type past a porous stretching cylinder with heat generation and chemical reaction

Sudarmozhi,
Iranian,
Khan
et al. 2023
International Journal of Thermofluids
9
0
0
0
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Bejan number and entropy generation analysis of unsteady MHD non-Newtonian micropolar squeezed trihybrid nanofluid flow

Sharif,
Fatmawati,
Habib
et al. 2024
Partial Differential Equations in Applied Mathematics
6
0
0
0
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