Polder tensor

The Polder tensor is a tensor introduced by Dirk Polder^[1] for the description of magnetic permeability of ferrites.^[2] The tensor notation needs to be used because ferrimagnetic material becomes anisotropic in the presence of a magnetizing field.

The tensor is described mathematically as:^[3]

B={\begin{bmatrix}\mu &j\kappa &0\\-j\kappa &\mu &0\\0&0&\mu _{0}\end{bmatrix}}H

Neglecting the effects of damping, the components of the tensor are given by

\mu =\mu _{0}\left(1+{\frac {\omega _{0}\omega _{m}}{\omega _{0}^{2}-\omega ^{2}}}\right)

\kappa =\mu _{0}{\frac {\omega \omega _{m}}{{\omega _{0}}^{2}-\omega ^{2}}}

where

\omega _{0}=\gamma \mu _{0}H_{0}\

\omega _{m}=\gamma \mu _{0}M\

\omega =2\pi f

$\gamma =1.11\times 10^{5}\cdot g\,\,$ (rad / s) / (A / m) is the effective gyromagnetic ratio and $g$ , the so-called effective g-factor (physics), is a ferrite material constant typically in the range of 1.5 - 2.6, depending on the particular ferrite material. $f$ is the frequency of the RF/microwave signal propagating through the ferrite, $H_{0}$ is the internal magnetic bias field, $M$ is the magnetization of the ferrite material and $\mu _{0}$ is the magnetic permeability of free space.

To simplify computations, the radian frequencies of $\omega _{0},\,\omega _{m},\,$ and $\omega$ can be replaced with frequencies (Hz) in the equations for $\mu$ and $\kappa$ because the $2\pi$ factor cancels. In this case, $\gamma =1.76\times 10^{4}\cdot g\,\,$ Hz / (A / m) $=1.40\cdot g\,\,$ MHz / Oe. If CGS units are used, computations can be further simplified because the $\mu _{0}$ factor can be dropped.

References[edit]

^ D. Polder, On the theory of ferromagnetic resonance, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 40, 1949 doi:10.1080/14786444908561215
^ G. G. Robbrecht, J. L. Verhaeghe, Measurements of the Permeability Tensor for Ferroxcube, Letters to Nature, Nature 182, 1080 (18 October 1958), doi:10.1038/1821080a0
^ Marqués, Ricardo; Martin, Ferran; Sorolla, Mario (2008). Metamaterials with Negative Parameters: Theory, Design, and Microwave Applications. Wiley. p. 93. ISBN 978-0-470-19172-9.

[1] D. Polder, On the theory of ferromagnetic resonance, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 40, 1949 doi:10.1080/14786444908561215

[2] G. G. Robbrecht, J. L. Verhaeghe, Measurements of the Permeability Tensor for Ferroxcube, Letters to Nature, Nature 182, 1080 (18 October 1958), doi:10.1038/1821080a0

[3] Marqués, Ricardo; Martin, Ferran; Sorolla, Mario (2008). Metamaterials with Negative Parameters: Theory, Design, and Microwave Applications. Wiley. p. 93. ISBN 978-0-470-19172-9.

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