Simulation of Magnetic Fluid Flow based on Maxwell's Equations and Navier-Stokes Equations

Abstract: The magnetic liquids such as ferrofluids, biocompatible magnetic nanocarrier, play an important role as drug carriers in the human body. Based on Maxwell's equation and Navier-Stokes equations, a time-dependent analysis of a twodimensional computational model of magnetic fluid flow is purposed. The FEM is applied to solve Maxwell's equation for a static magnetic field and Navier-Stokes equations for fluid dynamics. The result of magnetic field has some influences to ferrofluid dynamic flow in blood vessel.

“…A magnetic potential vector is A and the magnetization vector is M. Equation (7) and (8) [9] describe magnetization in x and y direction that is used in equation (9) and (10) [10]. To simulate blood flow in model, the x direction, v, follows a sinusoidal expression in time as illustrated in equation (11).…”

“…The area of eddy flow is focused only in the area that magnet is place as shown in Figure 9. The wedgelike model improves resolution of focal area compared with two magnets model [11].…”

A Computational Model of Magnetic Drug Targeting in Blood Vessel using Finite Element Method

“…A magnetic potential vector is A and the magnetization vector is M. Equation (7) and (8) [9] describe magnetization in x and y direction that is used in equation (9) and (10) [10]. To simulate blood flow in model, the x direction, v, follows a sinusoidal expression in time as illustrated in equation (11).…”

“…The area of eddy flow is focused only in the area that magnet is place as shown in Figure 9. The wedgelike model improves resolution of focal area compared with two magnets model [11].…”

A Computational Model of Magnetic Drug Targeting in Blood Vessel using Finite Element Method