Title :
Finite-Temperature Micromagnetism
Author :
Skomski, Ralph ; Kumar, Pranaw ; Hadjipanayis, G.C. ; Sellmyer, David J.
Author_Institution :
Dept. of Phys. & Astron., Univ. of Nebraska, Lincoln, NE, USA
Abstract :
It is investigated how magnetic hysteresis is affected by finite-temperature excitations, using soft regions in hard-magnetic matrices as model systems. In lowest order, magnetization processes are described by the traditional approach of using finite-temperature materials constants such as K1 (T). Nanoscale excitations are usually small perturbations. For example, a Bloch summation over all magnon wave vectors shows that remanence is slightly enhanced, because long-wavelength excitations are suppressed. However, a reverse magnetic field enhances the effect of thermal excitations and causes a small reduction of the coercivity. To describe such effects, we advocate micromagnetic calculations where finite-temperature fluctuations are treated as small corrections to the traditional approach, as contrasted to full-scale Monte Carlo simulations.
Keywords :
Monte Carlo methods; cobalt alloys; coercive force; fluctuations; iron; magnetic hysteresis; magnetic particles; magnetisation reversal; magnons; micromagnetics; nanocomposites; nanomagnetics; nanoparticles; neodymium alloys; permanent magnets; remanence; soft magnetic materials; Bloch summation; Monte Carlo simulation; NdCo5-Fe; coercivity; finite temperature fluctuation; finite temperature material constant; hard magnetic matrices; hard-soft nanocomposites; magnetic hysteresis; magnetization; magnon wave vector; micromagnetism; nanoparticle; nanoscale excitation; perturbation method; remanence; reverse magnetic field effects; thermal excitation; Anisotropic magnetoresistance; Iron; Magnetic hysteresis; Micromagnetics; Nanoscale devices; Perpendicular magnetic anisotropy; Coercivity; finite-temperature magnetism; micromagnetism; remanence;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2247386
