Author :
Pardavi-Horvath, Martha ; Vertesy, Gabor ; Hernando, Antonio
Abstract :
The time sequence of individual switching events was measured between 50°C and 88°C in an applied field H*, on a two dimensional square array of single domain garnet particles, switching by rotation against anisotropy energy barriers. The system is stable against thermal excitation because there are no low energy domain wall (DW) processes present, and no thermal aftereffect takes place at room temperature. However, at elevated temperatures the anisotropy barriers are decreased, and thermal relaxation by rotation was observed. In the regime of rotational switching the thermal relaxation process depends very weakly on the magnetic field. The aftereffect can be described by n(t)=n0(1-exp(-t/τ)). At T=50°C, τ=(77±7) s, decreasing to (24±4)s at 88 C. As expected, at a given temperature τ is practically independent of H*, demonstrating that, in contrast to aftereffect in materials involving DW motion, the aftereffect in two dimensional arrays, switching by rotation, is not sensitive to the applied field
Keywords :
arrays; garnets; magnetic aftereffect; magnetic domains; magnetic particles; magnetic switching; magnetisation; anisotropy barriers; anisotropy energy barriers; applied field; elevated temperatures; individual switching events; room temperature; rotation; rotational aftereffect; rotational switching; single domain garnet particles; single domain particles; thermal excitation; thermal relaxation; time sequence; two dimensional arrays; two dimensional square array; Anisotropic magnetoresistance; Energy barrier; Energy measurement; Garnets; Magnetic domain walls; Magnetic field measurement; Particle measurements; Rotation measurement; Temperature; Time measurement;
