Abstract
The study of biomagnetic fluid flow and heat transfer containing magnetic particles through an unsteady stretching/shrinking cylinder was numerically investigated in this manuscript. Biomagnetic fluid namely blood taken as base fluid and CoFe2O4 as magnetic particles. Where blood acts as an electrically conducting fluid along with magnetization/polarization. The main concentration is to study a time-dependent biomagnetic fluid flow with magnetic particles that passed through a two dimensional stretching/shrinking cylinder under the influence of thermal radiation, heat source and partial slip condition which has not been studied yet as far as best knowledge of authors. This model is consistent with the principles of magnetohydrodynamic and ferrohydrodynamic. The flow equations, such as momentum, energy which is described physically by a system of coupled, nonlinear partial differential equation with appropriate boundary conditions and converted into a nonlinear system of ordinary differential equations by using suitable similarity transformations. The resultant ODEs numerically solved by applying by applying an efficient numerical technique based on a common finite differencing method along with central differencing, tridiagonal matrix manipulation and an iterative procedure. The values assigned to the parameters are compatible with human body conditions. The numerous results concerning velocity, temperature and pressure field, as well as the skin friction and the rate of heat transfer, are presented for the parameters exhibiting physical significance, such as ferromagnetic interaction parameter, magnetic field parameter, volume fraction, unsteady parameter, curvature parameter, etc. The main numerical findings are that the fluid velocity is decreased as the ferromagnetic number is enhanced gradually in both stretching or shrinking cases whereas, the opposite behavior is found for the skin friction coefficient. The rate of heat transfer with ferromagnetic interaction parameter was also monitored and found that opposite behavior occurs for stretching and shrinking cases. Comparisons were made to check the accuracy of the present numerical results with published literature and found to be in excellent agreement. Hopefully, this proposed model will control the blood flow rate, as well as the rate of heat transfer, such as magnetic hyperthermia.
Highlights
The results presented concerning the velocity, temperature, pressure distributions, skin friction coefficient and rate of heat transfer, show that the blood-CoFe2O4 flow is appreciably influenced by the application of magnetic field, where suction parameter plays a vital role
The effects of thermal radiation, velocity slip condition, heat source are taken into consideration
The governing set of partial differential equations is converted into ordinary differential equations along with appropriate boundary condito Figure 17b
Summary
Magnetochemistry 2022, 8, 27 cancer therapy (hyperthermia), magnetic drug and gene delivery, magnetic separation, reducing blood during surgeries, tissue engineering as early mentioned by [1–5] as theoretically and experimentally. To the author’s best knowledge, the study of a biomagnetic fluid model (blood flow model) containing magnetic particles through an unsteady stretching/shrinking cylindrical has not been studied yet so far. In cancer treatment magnetic particles are transferred into cancer cells and enhance the heat (using the hyperthermia therapy method) in presence of an applied magnetic field. Blood is deliberated as magnetic fluid due to the presence of red blood cells that contain the hemoglobin molecule which is a form of iron oxide that is present at a uniquely high concentration in the mature red blood cells [5,6]
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