Temperature controlled switchable exchange bias and coercivity in spin glass/ferromagnet multilayers under tilting magnetizing

Abstract

A modified Monte Carlo method is used to study the temperature dependence of exchange bias and coercivity behaviors in ferromagnetic layers sandwiched by spin glass layers based on three stacking structures. An interesting phenomenon of 100% temperature controlled switch between the exchange bias field and coercivity is observed. Angular dependence of exchange bias field and coercivity behaviors indicate that there exists a minimum nonzero angle between the magnetic field and ferromagnet/spin glass easy axis, depending on the stacking structure, to achieve a complete switch. We further study the thermal remnant magnetization, the Zeeman and exchange energy behaviors during hysteretic measurements and the magnetic training effect at different temperatures, designating that the spin glassy dynamics is crucial for such a smooth and full switch. This finding shows potential in designing an applicable thermally assisted read/write switchable spintronic devices, achieved simply by rotational magnetizing and nanostructure engineering.