4 pages, 2 eps figuresWe investigate the magnetization dynamics of a conducting magnetic nanoparticle weakly coupled to source and drain electrodes, under the assumption that all relaxation comes from exchange of electrons with the electrodes. The magnetization dynamics is characterized by a relaxation time $t_1$, which strongly depends on temperature, bias voltage, and gate voltage. While a direct measure of a nanoparticle magnetization might be difficult, we find that $t_1$ can be determined through a time resolved transport measurement. For a suitable choice of gate voltage and bias voltage, the magnetization performs a bias-driven Brownian motion regardless of the presence of anisotropy
15 pages, 6 figuresInternational audienceWe consider a small metallic particle (quantum dot) where f...
The dynamical motion of the magnetization plays a key role in the properties of magnetic materials. ...
The low-temperature dynamics of a magnetic nanoparticle system (γ‐Fe2O3γ‐Fe2O3—alginate nanocomposit...
Magnetic relaxation divided into the Néel and Brownian regimes determines the magnetization dynamics...
The intriguing properties of magnetic nanoparticles have sparked a growing number of theoretical stu...
Magnetic relaxations determine the magnetization properties of magnetic nanoparticles for biomedical...
Magnetic nanoparticles in suspensions provide fascinating model systems to study field-induced effec...
The dependence of magnetic relaxation on particle parameters, such as the size and anisotropy, has b...
<p>The normalized mean magnetization is identical if the field and the relaxation time are multiplie...
In nanomagnetism, the studies of magnetic nanoparticle systems are of particular interest from both ...
International audienceThe magnetization reversal time of magnetic nanoparticles is investigated in t...
Properties of magnetic nanoparticles in the Brownian relaxation region were studied. Using the magne...
The efficient development and utilisation of magnetic nanoparticles (MNPs) for applications in enhan...
The damping of magnetization processes in nanostructures is investigated by Fokker–Planck-type model...
The efficient development and utilisation of magnetic nanoparticles (MNPs) for applications in enhan...
15 pages, 6 figuresInternational audienceWe consider a small metallic particle (quantum dot) where f...
The dynamical motion of the magnetization plays a key role in the properties of magnetic materials. ...
The low-temperature dynamics of a magnetic nanoparticle system (γ‐Fe2O3γ‐Fe2O3—alginate nanocomposit...
Magnetic relaxation divided into the Néel and Brownian regimes determines the magnetization dynamics...
The intriguing properties of magnetic nanoparticles have sparked a growing number of theoretical stu...
Magnetic relaxations determine the magnetization properties of magnetic nanoparticles for biomedical...
Magnetic nanoparticles in suspensions provide fascinating model systems to study field-induced effec...
The dependence of magnetic relaxation on particle parameters, such as the size and anisotropy, has b...
<p>The normalized mean magnetization is identical if the field and the relaxation time are multiplie...
In nanomagnetism, the studies of magnetic nanoparticle systems are of particular interest from both ...
International audienceThe magnetization reversal time of magnetic nanoparticles is investigated in t...
Properties of magnetic nanoparticles in the Brownian relaxation region were studied. Using the magne...
The efficient development and utilisation of magnetic nanoparticles (MNPs) for applications in enhan...
The damping of magnetization processes in nanostructures is investigated by Fokker–Planck-type model...
The efficient development and utilisation of magnetic nanoparticles (MNPs) for applications in enhan...
15 pages, 6 figuresInternational audienceWe consider a small metallic particle (quantum dot) where f...
The dynamical motion of the magnetization plays a key role in the properties of magnetic materials. ...
The low-temperature dynamics of a magnetic nanoparticle system (γ‐Fe2O3γ‐Fe2O3—alginate nanocomposit...