Type of Document Dissertation Author Williams, Alicia Marie Author's Email Address firstname.lastname@example.org URN etd-11032008-220541 Title The Hydrodynamics of Ferrofluid Aggregates Degree PhD Department Mechanical Engineering Advisory Committee
Advisor Name Title Vlachos, Pavlos P. Committee Chair Battaglia, Francine Committee Member Paul, Mark R. Committee Member Puri, Ishwar K. Committee Member Stremler, Mark A. Committee Member Keywords
- Magnetic Drug Targeting
Date of Defense 2008-08-01 Availability unrestricted AbstractFerrofluids are comprised of subdomain particles of magnetite or iron oxide material that can become magnetized in the presence of a magnetic field. These unique liquids are being incorporated into many new applications due to the ability to control them at a distance using magnetic fields. However, although our understanding of the dynamics of ferrofluids has evolved, many aspects of ferrohydrodynamics remain largely unexplored, especially experimentally.
This study is the first to characterize the stability and internal dynamics of accumulating or dispersing ferrofluid aggregates spanning the stable, low Reynolds number behavior to unstable, higher Reynolds numbers. The dynamics of ferrofluid aggregates are governed by the interaction between the bulk flow shear stresses acting to wash away the aggregate and magnetic body forces acting to retain them at the magnet location. This interaction results in different aggregate dynamics, including the stretching and coagulation of the aggregate to Kelvin-Helmholtz shedding from the aggregate interface as identified by focused shadowgraphs.
Using TRDPIV, the first time-resolved flow field measurements conducted in ferrofluids reveal the presence of a three-stage process by which the ferrofluid interacts with a pulsatile bulk flow. An expanded parametric study of the effect of Reynolds number, magnetic field strength, and flow unsteadiness reveals that the increased field results can result in the lifting and wash away of the aggregate by means of vortex strengthening. In pulsatile flow, different forms of the three-stage interaction occur based on magnetic field, flow rate, and Reynolds number.
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