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Abstract
The study of thin film flow over a stretching sheet holds significant importance from an industrial perspective due to its relevance in various manufacturing and engineering processes. In the present investigation, we delved into the combined influence of non-uniform heat source/sink on the governing heat and mass transfer equations in a thin liquid film on a permeable stretching surface. We have considered the nonlinear thermal radiation and implemented convective-type boundary conditions. Our analysis examined the effects of crucial physical parameters, including non-uniform heat source/sink, thermal radiation, chemical reaction, magnetic parameter , Prandtl number, Schmidt number, and unsteadiness parameter in the range [−3.5, 2.0], [−2, 5], [0, 1], [0.3, 4.0], [1, 7], [0.8, 1.7], [0.7, 2.0], respectively. It is found that a non-uniform heat source/sink mitigated the temperature gradient, while an elevation in the Schmidt number intensified the mass transfer rate. The validation process enhanced the robustness and reliability of our numerical simulations.
Acknowledgments
The authors would like to extend their sincere gratitude to the Reviewers and Editor-in-Chief for their valuable comments and constructive suggestions. These insightful inputs have significantly enhanced the quality of this work, aligning it with the standards expected by this esteemed journal. The pointwise suggestions of the reviewers has played a pivotal role in refining and elevating the content to meet the high standards of this reputable publication.
Disclosure statement
No potential conflict of interest was reported by the author(s).