Biased magnetic materials in RAM applications

The magnetization of a ferro- or ferri-magnetic material has been modeled with the Landau-Lifshitz-Gilbert (LLG) equation. In this

model demagnetization effects are included. By applying a linearized

small signal model of the LLG equation, it was found that the material

can be described by an effective permeability and with the aid of a

static external biasing field, the material can be switched between a

Lorentz-like material and a material that exhibits a magnetic

conductivity. Furthermore, the reflection coefficient for normally

impinging waves on a PEC covered with a ferro/ferri- magnetic

material, biased in the normal direction, is calculated. When the

material is switched into the resonance mode, two distinct resonance

frequencies in the reflection coefficient were found, one associated

with the precession frequency of the magnetization and the other

associated with the thickness of the layer. The former of these

resonance frequencies can be controlled by the bias field and for a

bias field strength close to the saturation magnetization, where the

material starts to exhibit a magnetic conductivity, low reflection

(around -20 dB) for a quite large bandwidth (more than two decades)

can be achieved.