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Paper detail

Entropy-reduced retention times in magnetic memory elements: A case of the Meyer-Neldel Compensation Rule

We compute mean waiting times between thermally-activated magnetization reversals in a nanodisk with parameters similar to a free CoFeB layer used in magnetic random access memories. By combining Langer's theory and forward flux sampling simulations, we show that the Arrhenius prefactor can take values up to 10$^{21}$ Hz, orders of magnitude beyond the value of 10$^{9}$ Hz typically assumed, and varies drastically as a function of material parameters. We show that the prefactor behaves like an exponential of the activation energy, which highlights a case of the Meyer-Neldel compensation rule. This suggests that modeling information retention times with a barrier-independent prefactor in such magnetic storage elements is not justified.

preprint2020arXivOpen access
L. DesplatJ. -V. Kim
cond-mat.stat-mechcond-mat.mes-hall
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L. DesplatJ. -V. Kim

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