24 research outputs found
The Nature and Validity of the RKKY limit of exchange coupling in magnetic trilayers
The effects on the exchange coupling in magnetic trilayers due to the
presence of a spin-independent potential well are investigated. It is shown
that within the RKKY theory no bias nor extra periods of oscillation associated
with the depth of the well are found, contrary to what has been claimed in
recent works. The range of validity of the RKKY theory is also discussed.Comment: 10, RevTe
Fundamental Oscillation Periods of the Interlayer Exchange Coupling beyond the RKKY Approximation
A general method for obtaining the oscillation periods of the interlayer
exchange coupling is presented. It is shown that it is possible for the
coupling to oscillate with additional periods beyond the ones predicted by the
RKKY theory. The relation between the oscillation periods and the spacer Fermi
surface is clarified, showing that non-RKKY periods do not bear a direct
correspondence with the Fermi surface. The interesting case of a FCC(110)
structure is investigated, unmistakably proving the existence and relevance of
non-RKKY oscillations. The general conditions for the occurrence of non-RKKY
oscillations are also presented.Comment: 34 pages, 10 figures ; to appear in J. Phys.: Condens. Mat
Model for spin coupling disorder effects on the susceptibility of antiferromagnetic nanochains
The temperature dependence of the static magnetic susceptibility of
exchange-disordered antiferromagnetic Heisenberg spin-1/2 finite chains with an
odd number of spins is investigated as a function of size and type of disorder
in the exchange coupling. Two models for the exchange disorder distribution are
considered. At sufficiently low temperatures each chain behaves like an
isolated spin-1/2 particle. As the size of the chains increases, this analogy
is lost and the chains evolve into the thermodynamic limit behavior. The
present study provides a simple criterion, based on susceptibility
measurements, to establish when odd-sized chains effectively simulate a single
spin-1/2 particle.Comment: 8 pages, 3 figure
Magnetic behavior of nanoparticles in patterned thin films
The magnetic behavior of truncated conical nanoparticles in patterned thin
films is investigated as a function of their size and shape. Using a scaling
technique, phase diagrams giving the relative stability of characteristic
internal magnetic structures of the particles are obtained. The role of the
uniaxial anisotropy in determining the magnetic properties of such systems is
discussed, and a simple method for stablishing its strength is proposed.Comment: 4 pages, 4 figure
Hole concentration in a diluted ferromagnetic semiconductor
We consider a mean-field approach to the hole-mediated ferromagnetism in
III-V Mn-based semiconductor compounds to discuss the dependence of the hole
density on that of Mn sites in Ga_{1-x}Mn_xAs. The hole concentration, p, as a
function of the fraction of Mn sites, x, is parametrized in terms of the
product m*J_{pd}^2 (where m* is the hole effective mass and J_{pd} is the
Kondo-like hole/local-moment coupling), and the critical temperature Tc. By
using experimental data for these quantities, we have established the
dependence of the hole concentration with x, which can be associated with the
occurrence of a reentrant metal-insulator transition taking place in the hole
gas. We also calculate the dependence of the Mn magnetization with x, for
different temperatures (T), and found that as T increases, the width of the
composition-dependent magnetization decreases drammatically, and that the
magnetization maxima also decreases, indicating the need for quality-control of
Mn-doping composition in diluted magnetic semiconductor devices.Comment: 4 pages, 3 figures, RevTeX 3; Fig. 1 changed, new references adde
Exchange coupling between magnetic layers across non-magnetic superlattices
The oscillation periods of the interlayer exchange coupling are investigated
when two magnetic layers are separated by a metallic superlattice of two
distinct non-magnetic materials. In spite of the conventional behaviour of the
coupling as a function of the spacer thickness, new periods arise when the
coupling is looked upon as a function of the number of cells of the
superlattice. The new periodicity results from the deformation of the
corresponding Fermi surface, which is explicitly related to a few controllable
parameters, allowing the oscillation periods to be tuned.Comment: 13 pages; 5 figures; To appear in J. Phys.: Cond. Matte
Quantum Diffusion and Localization in Disordered Electronic Systems
The diffusion of electronic wave packets in one-dimensional systems with
on-site, binary disorder is numerically investigated within the framework of a
single-band tight-binding model. Fractal properties are incorporated by
assuming that the distribution of distances between consecutive
impurities obeys a power law, . For suitable
ranges of , one finds system-wide anomalous diffusion. Asymmetric
diffusion effects are introduced through the application of an external
electric field, leading to results similar to those observed in the case of
photogenerated electron-hole plasmas in tilted InP/InGaAs/InP quantum wells.Comment: RevTex4, 6 pages, 6 .eps figures: published versio