Dynamically Induced Magnetic Moment of a Magnetic Dipole System
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Anatoliy Michailovich Shutyǐ
Abstract
The systems of three and four spherical bodies with the dipole magnetic moment have been investigated using a numerical analysis. It was shown that in the initial state with the zero total magnetic moment under the influence of the alternating magnetic field, various regimes of the induced magnetic moment including quasistatic states are established. Revealed are the significant differences between these regimes related to different systems. The magnitude and direction of the magnetic moment of the system, as well the states of dynamic bistability, have been investigated. The possibilities of the induced magnetic moment control due to the changes in amplitude or frequency of the alternating field have been considered.
Funding statement: Research funding: This work was sponsored by Ministry of education and science of Russian Federation (N 3.175.2014K - of July 18, 2014)
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Artikel in diesem Heft
- Frontmatter
- A Short Remark on WAN Model for Electrospinning and Bubble Electrospinning and Its Development
- ICEEM07: Three-Dimensional Flow Optimization of a Pneumatic Pulsator Nozzle with a Continuous Adjoint
- Homogeneous Sono-Fenton Process: Statistical Modeling and Global Sensitivity Analysis
- Mathematical Characterization of Bénard-Type Geothermal Scenarios Using Discriminated Non-dimensionalization of the Governing Equations
- Sequential Maximum Likelihood Estimation for the Parameter of the Linear Drift Term of the Rayleigh Diffusion Process
- A Class of Exact Solution of (3+1)-Dimensional Generalized Shallow Water Equation System
- Dynamically Induced Magnetic Moment of a Magnetic Dipole System
Artikel in diesem Heft
- Frontmatter
- A Short Remark on WAN Model for Electrospinning and Bubble Electrospinning and Its Development
- ICEEM07: Three-Dimensional Flow Optimization of a Pneumatic Pulsator Nozzle with a Continuous Adjoint
- Homogeneous Sono-Fenton Process: Statistical Modeling and Global Sensitivity Analysis
- Mathematical Characterization of Bénard-Type Geothermal Scenarios Using Discriminated Non-dimensionalization of the Governing Equations
- Sequential Maximum Likelihood Estimation for the Parameter of the Linear Drift Term of the Rayleigh Diffusion Process
- A Class of Exact Solution of (3+1)-Dimensional Generalized Shallow Water Equation System
- Dynamically Induced Magnetic Moment of a Magnetic Dipole System
