Evaluation of power heat losses in multidomain iron particles under the influence of AC magnetic field in RF range

Authors:

• Andrzej Skumiel,
• Milena Kaczmarek-Klinowska,
• Milan Timko,
• Matus Molcan,
• Michał Rajnak

Abstract

The magnetic properties and hyperthermia effect were studied in a magnetorheological fluid (MRF) containing iron particles of 1μm to 5μm in diameter. The measurements showed that the magnetization in the saturation state reaches a value of 171 A · m² kg^-1 with very small values of coercivity and remanence. They also showed the ferromagnetic behavior in the system together with a value of the magnetic susceptibility of 1.7. Theoretical and experimental results of the calorimetric effect investigation under a changeable magnetic field of high frequency (f = 504 kHz) in an MRF will be presented in the article. The sample was subjected to an alternating magnetic field of different strengths (H = 0 to 4 kA m^-1. It results from a theoretical analysis that the heat power density (released in the MRF sample) referenced to the eddy current is proportional to the square of frequency, the magnetic field amplitude, and the iron grain diameter. Experimental results indicate that there are some reasons for the released heat energy such as: energy losses from magnetic hysteresis and eddy currents induced in the iron grains. If the magnetic field intensity amplitude grows, the participation of losses connected with magnetic hysteresis is increased. From the calorimetric measurements, the conclusion is as follows: for a magnetic field H<1946 Am^-1, the eddy current processes dominate in the heat generation mechanism, whereas hysteresis processes for the total release of thermal energy dominate for higher magnetic fields. Both mechanisms take equal parts in heating the tested sample at a magnetic field intensity amplitude H= 1946 A m^-1. The specific absorption rate referenced to the mass unit of the MRF sample at the amplitude of the magnetic field strength 4 kA m ^-1 equals 24.94 W kg^-1 at a frequency f = 504 kHz. © 2012 The Author(s).