Abstract
In this modern era, nanofluids are considered one of the advanced kinds of heat transferring fluids due to their enhanced thermal features. The present study is conducted to investigate that how the suspension of molybdenum-disulfide nanoparticles boosts the thermal performance of a Casson-type fluid. Sodium alginate (NaAlg) based nanofluid is contained inside a vertical channel of width d and it exhibits a flow due to the movement of the left wall. The walls are nested in a permeable medium, and a uniform magnetic field and radiation flux are also involved in determining flow patterns and thermal behavior of the nanofluid. Depending on velocity boundary conditions, the flow phenomenon is examined for three different situations. To evaluate the influence of shape factor, nanoparticles of blade, cylinder, platelet, and brick shapes are considered. The mathematical modeling is performed in the form of non-integer order operators, and a double fractional analysis is carried out by separately solving Caputo-Fabrizio and Atangana-Baleanu operators based fractional models. The system of coupled PDEs is converted to ODEs by operating the Laplace transformation, and Zakian’s algorithm is applied to approximate the Laplace inversion numerically. The solutions of flow and energy equations are presented in terms of graphical illustrations and tables to discuss important physical aspects of the observed problem. Moreover, a detailed inspection on shear stress and Nusselt number is carried out to get a deep insight into skin friction and heat transfer mechanisms. It is analyzed that the suspension of nanoparticles leads to ameliorating the heat transfer rate up to 9.5%. To serve the purpose of achieving maximum heat transfer rate and reduced skin friction, the Atangana-Baleanu operator based fractional model is more effective. Furthermore, it is perceived that velocity and energy functions of the nanofluid exhibit significant variations because of the different shapes of nanoparticles.
Highlights
Nanotechnology, described as the development of atomic-scale structures through appropriate manipulation of molecules and atoms, is influencing a wide variety of modern physical phenomena in today’s world
The evaluation of thermal and physical features of sodium alginate due to the addition of MoS2 nanoparticles is studied. This purpose is served via fractional modeling of the problem and results are compared for Atangana-Baleanu and CaputoFabrizio operators based models
Semi-exact solutions for these two fractional models are computed by jointly employing the Laplace transform and Zakian’s numerical inversion method
Summary
Nanotechnology, described as the development of atomic-scale structures through appropriate manipulation of molecules and atoms, is influencing a wide variety of modern physical phenomena in today’s world. Synthetic chemistry has progressed to the extent that it is possible to create nanoscopic molecules of almost any shape and structure that can be used to prepare a broad range of effective chemicals such as pharmaceuticals and industrial polymers. Nanomedicine is another important application of nanotechnology. During the period of last forty years, nanofluids have piqued the attention of a great number of scientists due to their practical applications and enhanced physical characteristics over conventional fluids
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