We present a general method to evaluate the long-time magnetization decay in granular magnetic systems. The method is based on Arrhenius-Neel kinetics with the evaluation of the energy barriers in a multidimensional space. To establish a possible reversal mode, we suggest the use of Metropolis Monte Carlo and for the mode statistical sampling-the kinetic Monte Carlo criteria. The examples considered include long-time magnetization decay in CoCrPt low-magnetization longitudinal recording media and in a collection of Co particles with different concentrations
An efficient method for computing thermodynamic equilibrium states at the micromagnetic length scale...
International audienceThermal fluctuations of nanomagnets driven by spin-polarized currents are trea...
Granular magnetic recording media with perpendicular anisotropy are the basis of information storage...
International audienceIn this article, we are interested in the behaviour of a single ferromagnetic ...
Magnetization reversal in Co nanostructures is simulated over a wide range of time-scales, from fast...
Thermally activated magnetization reversal is of great importance in areas such as permanent magneti...
Heat-assisted magnetic recording (HAMR) technology represents the most promising candidate to replac...
Information loss due to thermal activation is a major concern in ultrahigh-density magnetic recordin...
short time scale breakdown of the Arrhenius-Neel law for a single magnetic moment is demonstrated an...
AbstractA semi-analytic description of recording media grainsʼ magnetization flipping in a magnetic ...
Magnetic materials are now controllable down to a nanometer length scale and, hence, there is a broa...
The dynamic process of assisted magnetic switchings has been simulated to investigate the associated...
The continuing need for increased information storage capacity has driven a remarkable increase in a...
With increasing demand for high density magnetic recording devices a paradigm shift is required to o...
The current state of the art technology for ultra-high density magnetic storage is based on heat ass...
An efficient method for computing thermodynamic equilibrium states at the micromagnetic length scale...
International audienceThermal fluctuations of nanomagnets driven by spin-polarized currents are trea...
Granular magnetic recording media with perpendicular anisotropy are the basis of information storage...
International audienceIn this article, we are interested in the behaviour of a single ferromagnetic ...
Magnetization reversal in Co nanostructures is simulated over a wide range of time-scales, from fast...
Thermally activated magnetization reversal is of great importance in areas such as permanent magneti...
Heat-assisted magnetic recording (HAMR) technology represents the most promising candidate to replac...
Information loss due to thermal activation is a major concern in ultrahigh-density magnetic recordin...
short time scale breakdown of the Arrhenius-Neel law for a single magnetic moment is demonstrated an...
AbstractA semi-analytic description of recording media grainsʼ magnetization flipping in a magnetic ...
Magnetic materials are now controllable down to a nanometer length scale and, hence, there is a broa...
The dynamic process of assisted magnetic switchings has been simulated to investigate the associated...
The continuing need for increased information storage capacity has driven a remarkable increase in a...
With increasing demand for high density magnetic recording devices a paradigm shift is required to o...
The current state of the art technology for ultra-high density magnetic storage is based on heat ass...
An efficient method for computing thermodynamic equilibrium states at the micromagnetic length scale...
International audienceThermal fluctuations of nanomagnets driven by spin-polarized currents are trea...
Granular magnetic recording media with perpendicular anisotropy are the basis of information storage...