Heat Transfer Mechanisms and Applications
Submission deadline: 2024-02-29
Section Collection Editors

Section Collection Information

Dear Colleagues,

With the advancement of science and technology, scientists are studying the mechanism of heat and mass transfer, which has important theoretical significance and practical application value due to its significant utility in energy production, producing cooling in atomic reactors, improving biomedical, etc. The nanofluids are regarded to be more thermally efficient than conventional heat transfer fluids. It is a well-known fact that the suspension of nanoparticles in nanofluids depends on preparation and stability, shape and size, volume fraction, and temperature parameters, as the suspension of nanoparticles exemplifies ideal and efficient heat transfer. This intensified to increase the energy efficiency of the various types of heat exchange systems utilized in several physical, mechanical, and engineering applications.

 

Frequently, the addition of nanoparticles to a base fluid increases its heat transfer capabilities, but it can also impair the base fluid's flow capabilities. Consequently, it is essential to optimize thermophysical characteristics by incorporating nanomaterials. In light of this, the hybrid nanofluid increases the surface heat transfer rate relative to the nanofluid and simple fluid.

 

Thus, we are interested in the Applied/Computational mathematics (Fluid dynamics) subjects in the framework of mathematical modeling, magnetohydrodynamic, porous medium, thermal convection, heat source, and chemical reaction, the heat and mass transfer rate of mano/hybrid nanofluid flow through various geometries. These discoveries include studies on the thermal conductivity of nanoparticles, the viscosity of nanofluid, mathematical mechanisms of fluid dynamical problems, the implication of different numerical methods and it is necessary to rationalize the various aspects studied in the literature, providing a framework for future standards and applications. Research articles and reviews in this area of study are welcome. We look forward to receiving your contributions.


Leading Section Editor:

Dr. Liaqat Ali,


Support Section Editors:

Prof.Ahmed Rezk

Dr.Mohamad EL KADRI

Dr. P. Ragupathi

Keywords

Fluid flow; Heat and mass transfer; Magnetohydrodynamics; Mathematical modeling; Nanofluid; Hybrid nanofluids; Aggregation; Numerical solution of ODEs/PDEs; Thermal convection; Newtonian/non-Newtonian fluids; Porous medium.

Published Paper