Add to ORKGWe study, both analytically and numerically, the phenomenon of energy dissipation in single-domain ferromagnetic nanoparticles driven by an alternating magnetic field. Our interest is focused on the power loss resulting from the Landau-Lifshitz-Gilbert equation, which describes the precessional motion of the nanoparticle magnetic moment. We determine the power loss as a function of the field amplitude and frequency and analyze its dependence on different regimes of forced precession induced by circularly and linearly polarized magnetic fields. The conditions to maximize the nanoparticle heating are also analyzed
The magnetic moment of a single-domain nanoparticle can be effectively switched on an ultrashort tim...
The effect of interparticle interactions on the magnetization dynamics and energy dissipation rates ...
We solved the Landau-Lifshitz equations numerically to examine the time development of a system of m...
Using the Landau-Lifshitz equation, the dependencies of the power loss of the nanoparticle magnetic ...
We study dynamical and thermal effects that are induced in nanoparticle systems by a rotating magnet...
We study the effect of an elliptically polarized magnetic field on a system of non-interacting, sin...
The joint magnetic and mechanical motion of a ferromagnetic nanoparticle in a viscous fluid is consi...
The influence of the rotating magnetic field on the thermal stability of the precession modes of t...
We study the thermal stability of the periodic (P) and quasiperiodic (Q) precessional modes of the n...
The investigation of a sizable thermal enhancement of magnetization is put forward for uniaxial fer...
Single-domain ferromagnetic nanoparticle systems can be used to transfer energy from a time-dependen...
Computational and experimental results of thermally induced magnetization reversal in single-domain ...
We focus on an in-depth study of the forced dynamics of a ferromagnetic single-domain uniaxial nanop...
We considered the coupled motion of the magnetic moment of a ferromagnetic uniaxial nanoparticle and...
We present a simple simulation model for analysing magnetic and frictional losses of magnetic nano-p...
The magnetic moment of a single-domain nanoparticle can be effectively switched on an ultrashort tim...
The effect of interparticle interactions on the magnetization dynamics and energy dissipation rates ...
We solved the Landau-Lifshitz equations numerically to examine the time development of a system of m...
Using the Landau-Lifshitz equation, the dependencies of the power loss of the nanoparticle magnetic ...
We study dynamical and thermal effects that are induced in nanoparticle systems by a rotating magnet...
We study the effect of an elliptically polarized magnetic field on a system of non-interacting, sin...
The joint magnetic and mechanical motion of a ferromagnetic nanoparticle in a viscous fluid is consi...
The influence of the rotating magnetic field on the thermal stability of the precession modes of t...
We study the thermal stability of the periodic (P) and quasiperiodic (Q) precessional modes of the n...
The investigation of a sizable thermal enhancement of magnetization is put forward for uniaxial fer...
Single-domain ferromagnetic nanoparticle systems can be used to transfer energy from a time-dependen...
Computational and experimental results of thermally induced magnetization reversal in single-domain ...
We focus on an in-depth study of the forced dynamics of a ferromagnetic single-domain uniaxial nanop...
We considered the coupled motion of the magnetic moment of a ferromagnetic uniaxial nanoparticle and...
We present a simple simulation model for analysing magnetic and frictional losses of magnetic nano-p...
The magnetic moment of a single-domain nanoparticle can be effectively switched on an ultrashort tim...
The effect of interparticle interactions on the magnetization dynamics and energy dissipation rates ...
We solved the Landau-Lifshitz equations numerically to examine the time development of a system of m...