# Temperature Dependence of the Anisotropy Field of L10 FePt near the   Curie Temperature

**Authors:** H.J. Richter, G.J. Parker

arXiv: 1703.10921 · 2017-06-28

## TL;DR

This study investigates how the anisotropy field of L10 FePt varies near its Curie temperature, revealing that thermally activated magnetization reversal plays a significant role and is well described by conventional models.

## Contribution

The paper provides micromagnetic analysis showing that the anisotropy field follows a specific scaling law with a low beta value and highlights the importance of thermally activated reversal near T_c.

## Key findings

- Beta value near the lower end of literature range
- Thermally activated reversal is significant near T_c
- Reversal described by conventional theory with high frequency factor

## Abstract

Near the Curie temperature the anisotropy field of magnetically uniaxial L10 FePt is expected to follow the scaling law $(1-T/Tc)^\beta$ where $T$ is the temperature and $T_c$ the Curie temperature. In the literature $\beta$ values between 0.36 and 0.65 have been reported. Based on recording measurements and micromagnetic analysis, we show that only the values of $\beta$ near the low end of the reported range are compatible with the data. We also conclude that thermally activated magnetization reversal at temperatures near $T_c$ cannot be ignored, even at time scales smaller than 1 ns. We demonstrate that thermally activated magnetization reversal at temperatures close to $T_c$ is well described by conventional theory with a frequency factor $f_0$ of the order of $10^{12}$ Hz. It is reasoned that the unusually high value for $f_0$ is a consequence of the temperature-induced reduction of the degree of alignment of the micro-spins within the grains.

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Source: https://tomesphere.com/paper/1703.10921