Time depending magnetization of nanoparticles under radiofrequency fields: Experimental relaxation time in water for solid-liquid transition

Abstract

In application as hyperthermia and nanowarming, power dissipation arises when the time-dependent magnetization M(t) of an out-of-equilibrium system of nanoparticles lags behind the applied field H(t). The key parameter governing this process is the relaxation time τ of the system, which induces a phase shift φn between H(t) and every nth harmonic component of M(t). In this work, we present an expression for M(t) in terms of τ and the equilibrium magnetization, valid for any magnetic system exhibiting odd equilibrium response. From this calculation, we obtain a method for determining the effective τ of a MNPs sample directly from the experimental measurement of M(t). Additionally, we demonstrate that the power dissipation (SAR: Specific Absorption Rate) of any magnetic sample under a sinusoidal field can be obtained from the first harmonic component of M(t). As an illustrative application, we explore the variation of τ for magnetic MNPs in aqueous suspension during the melting process of the matrix. In this case, the change in τ can be understood as a result of the reorientation of the MNPs in the direction of the applied field as the matrix becomes liquid.

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