Title :
A homogenized energy framework for ferromagnetic hysteresis
Author :
Smith, R.C. ; Dapino, Marcelo J.
Author_Institution :
Dept. of Math., North Carolina State Univ., Raleigh, NC
fDate :
7/1/2006 12:00:00 AM
Abstract :
This paper focuses on the development of a homogenized energy model which quantifies certain facets of the direct magnetomechanical effect. In the first step of the development, Gibbs energy analysis at the lattice level is combined with Boltzmann principles to quantify the local average magnetization as a function of input fields and stresses. A macroscopic magnetization model, which incorporates the effects of polycrystallinity, material nonhomogeneities, stress-dependent interaction fields, and stress-dependent coercive behavior, is constructed through stochastic homogenization techniques based on the tenet that local coercive and interaction fields are manifestations of underlying distributions rather than constants. The resulting framework incorporates previous ferromagnetic hysteresis theory as a special case in the absence of applied stresses. Attributes of the framework are illustrated through comparison with previously published steel and iron data
Keywords :
Boltzmann equation; coercive force; free energy; magnetic hysteresis; magnetomechanical effects; stochastic processes; Boltzmann principles; Gibbs energy analysis; coercive behavior; direct magnetomechanical effect; ferromagnetic hysteresis theory; ferromagnetic materials; homogenized energy model; macroscopic magnetization model; magnetic hysteresis; magnetostrictive devices; material nonhomogeneities; nonlinear magnetics; polycrystallinity effect; stochastic homogenization; stress-dependent interaction; Hysteresis; Iron; Lattices; Magnetic analysis; Magnetic materials; Magnetization; Magnetomechanical effects; Steel; Stochastic processes; Stress; Actuators; Boltzmann equation; magnetic hysteresis; modeling; nonlinear magnetics;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2006.875717
