1,703 research outputs found
Exchange coupling induced antiferromagnetic-ferromagnetic transition in superlattices
Superlattices built from two antiferromagnetic (AFM) charge/orbital order
compounds, and , have been
studied as the thickness of () varied. High
structural quality thin films were obtained on substrates using the
pulsed laser deposition technique. An antiferromagnetic-to-ferromagnetic
transition, in addition to an enhancement of the coercivity, are observed as
the layer thickness increases. The small shift in the origin of the
field-cooled hysteresis loop along the field axis indicates the presence of
ferromagnetic and antiferromagnetic phases in the superlattices. We attribute
these features to the AFM spin fluctuations at the
interfaces resulting from the
strain effects.Comment: To be published in Phys. Rev.
Fretting wear of Ti(CxNy) PVD coatings under variable environmental conditions
Fretting wear as a specific type of degradation is defined as an oscillatory motion at small amplitude between two nominally stationary solid bodies in mutual contact. Under external stresses the interface is being damaged by debris generation and its successive ejections outside the contact area. A potential protection against fretting damage by means of hard coatings is being offered by different surface engineering techniques. For this study TiC, TiN and TiCN hard coatings manufactured by a PVD method have been selected and tested against smooth polycrystalline alumina ball. A fretting test programme has been carried out at the frequency of 5Hz, 100N normal load, 100µm displacement amplitude and at three values of a relative humidity: 10, 50 and 90% at 295-298K temperature. It turned out that the intensity of wear process was depending not only on loading conditions but on environmental ones as well. A significant impact of RH on wear rate and friction behaviour of the coatings under investigation has been observed. Two different damage mechanisms have been identified and related to the phenomena of debris oxidation and debris adhesion to the counterbody surface. In the latter case the debris deposited onto the surface of the alumina ball lead to a change of stress distribution at the interface and as a result to accelerated wear. In this work experiments with variable relative humidity increasing from 10% to 90% within 1 a single fretting test have been completed. It follows from these experiments that there exists an intermediate value of the RH at which the friction coefficient changes rapidly. Finally a dissipated energy approach has been applied in the work in order to quantify and compare fretting wear rates of different hard coatings
Manipulating superconductivity through the domain structure of a ferromagnet: experimental aspects and theoretical implications
In the present work we study experimentally the influence that the domain
structure of a fer- romagnet (FM) has on the properties of a superconductor
(SC) in bilayers and multilayers of La0.60Ca0.40MnO3/Nb and FePt/Nb proximity
hybrids. Specific experimental protocols that were employed in the performed
magnetization measurements enabled us to directly uncover a generic property of
FM/SC hybrids: in the absence of an external magnetic field, the multidomain
struc- ture of the FM promotes the nucleation of superconductivity, while its
monodomain state strongly suppresses it. Our experimental findings support
recent theoretical studies proposing that when an inhomogeneous exchange field
is offered by the FM to the SC the superconducting pairs are not susceptible to
pair-breaking.Comment: 4 pages, 4 figure
The interparticle interaction and crossover in critical lines on field-temperature plane in PrSrMnO nanoparticles
The magnetic properties and the effects of interparticle interaction on it
have been studied in nanoparticles of half doped PrSrMnO.
Three samples consisting of nanoparticles of different average particle sizes
are synthesized to render the variation in interparticle interaction. Though
all the samples crystallize in the same structure to that of their bulk
compound, the low temperature ferromagnetic-antiferromagnetic transition, which
is present in bulk compound, is not evident in the nanoparticles. Linear as
well as nonlinear ac susceptibility coupled with dc magnetic measurements have
shown the superparamagnetic behavior of these nanoparticles where the blocking
temperature increases with the increasing particle size. Presence of
interparticle interaction is confirmed from the temperature variation of
coercive field and the analysis of frequency dependent ac susceptibility. We
have identified the nature of this interaction to be of dipolar type, and show
that its strength decreases with the increasing particle size. The effect of
this dipolar interaction on magnetic properties is intriguing as the compounds
exhibit crossover from de Almeida-Thouless to Gabay-Toulouse like critical
lines on field-temperature plane above their respective interaction field. In
agreement with theoretical prediction, we infer that this crossover is induced
by the unidirectional anisotropy arising from interparticle interaction, and
this is confirmed from the presence of exchange bias phenomenon.Comment: To appear in Phys. Rev.
Large Coercivity in Nanostructured Rare-earth-free MnxGa Films
The magnetic hysteresis of MnxGa films exhibit remarkably large coercive
fields as high as 2.5 T when fabricated with nanoscale particles of a suitable
size and orientation. This coercivity is an order of magnitude larger than in
well-ordered epitaxial film counterparts and bulk materials. The enhanced
coercivity is attributed to the combination of large magnetocrystalline
anisotropy and ~ 50 nm size nanoparticles. The large coercivity is also
replicated in the electrical properties through the anomalous Hall effect. The
magnitude of the coercivity approaches that found in rare-earth magnets, making
them attractive for rare-earth-free magnet applications
Quenching of lamellar ordering in an n-alkane embedded in nanopores
We present an X-ray diffraction study of the normale alkane nonadecane
C_{19}H_{40} embedded in nanoporous Vycor glass. The confined molecular crystal
accomplishes a close-packed structure by alignment of the rod-like molecules
parallel to the pore axis while sacrificing one basic principle known from the
bulk state, i.e. the lamellar ordering of the molecules. Despite this disorder,
the phase transitions observed in the confined solid mimic the phase behavior
of the 3D unconfined crystal, though enriched by the appearance of a true
rotator phase known only from longer alkane chains.Comment: 7 pages, 3 figure
Micromagnetic simulations of sweep-rate dependent coercivity in perpendicular recording media
The results of micromagnetic simulations are presented which examine the
impact of thermal fluctuations on sweep rate dependent coercivities of both
single-layer and exchange-coupled-composite (ECC) perpendicular magnetic
recording media. M-H loops are calculated at four temperatures and sweep rates
spanning five decades with fields applied normal to the plane and at 45
degrees. The impact of interactions between grains is evaluated. The results
indicate a significantly weaker sweep-rate dependence for ECC media suggesting
more robustness to long-term thermal effects. Fitting the modeled results to
Sharrock-like scaling proposed by Feng and Visscher [J. Appl. Phys. 95, 7043
(2004)] is successful only in the case of single-layer media with the field
normal to the plane.Comment: 7 pages, 14 figure
Nanocrystallization and Amorphization Induced by Reactive Nitrogen Sputtering in Iron and Permalloy
Thin films of iron and permalloy Ni80Fe20 were prepared using an Ar+N2
mixture with magnetron sputtering technique at ambient temperature. The
nitrogen partial pressure, during sputtering process was varied in the range of
0 to 100%, keeping the total gas flow at constant. At lower nitrogen pressures
RN2<33% both Fe and NiFe, first form a nanocrystalline structure and an
increase in nitrogen partail pressure results in formation of an amorphous
structure. At intermediate nitrogen partial pressures, nitrides of Fe and NiFe
were obtained while at even higher nitrogen partial pressures, nitrides
themselves became nanocrystalline or amorphous. The surface, structural and
magnetic properties of the deposited films were studied using x-ray reflection
and diffraction, transmission electron microscopy, polarized neutron
reflectivity and using a DC extraction magnetometer. The growth behavior for
amorphous film was found different as compared with poly or nanocrystalline
films. The soft-magnetic properties of FeN were improved on nanocrystallization
while those of NiFeN were degraded. A mechanism inducing nanocrystallization
and amorphization in Fe and NiFe due to reactive nitrogen sputtering is
discussed in the present article.Comment: 13 Pages, 15 Figure
The Effect of Transfer Printing on Pentacene Thin-Film Crystal Structure
The thermal deposition and transfer Printing method had been used to produce
pentacene thin-films on SiO2/Si and plastic substrates (PMMA and PVP),
respectively. X-ray diffraction patterns of pentacene thin films showed
reflections associated with highly ordered polycrystalline films and a
coexistence of two polymorph phases classified by their d-spacing, d(001): 14.4
and 15.4 A.The dependence of the c-axis correlation length and the phase
fraction on the film thickness and printing temperature were measured. A
transition from the 15.4 A phase towards 14.4 A phase was also observed with
increasing film thickness. An increase in the c-axis correlation length of
approximately 12% ~16% was observed for Pn films transfer printed onto a PMMA
coated PET substrate at 100~120 C as compared to as-grown Pn films on SiO2/Si
substrates. The transfer printing method is shown to be an attractive for the
fabrication of pentacene thin-film transistors on flexible substrates partly
because of the resulting improvement in the quality of the pentacene film.Comment: 5 pages, 5 figure
Ultra-fast magnetisation rates within the Landau-Lifshitz-Bloch model
The ultra-fast magnetisation relaxation rates during the laser-induced
magnetisation process are analyzed in terms of the Landau-Lifshitz-Bloch (LLB)
equation for different values of spin . The LLB equation is equivalent in
the limit to the atomistic Landau-Lifshitz-Gilbert (LLG)
Langevin dynamics and for to the M3TM model [B. Koopmans, {\em et al.}
Nature Mat. \textbf{9} (2010) 259]. Within the LLB model the ultra-fast
demagnetisation time () and the transverse damping ()
are parameterized by the intrinsic coupling-to-the-bath parameter ,
defined by microscopic spin-flip rate. We show that for the phonon-mediated
Elliott-Yafet mechanism, is proportional to the ratio between the
non-equilibrium phonon and electron temperatures.
We investigate the influence of the finite spin number and the scattering
rate parameter on the magnetisation relaxation rates. The relation
between the fs demagnetisation rate and the LLG damping, provided by the LLB
theory, is checked basing on the available experimental data. A good agreement
is obtained for Ni, Co and Gd favoring the idea that the same intrinsic
scattering process is acting on the femtosecond and nanosecond timescale.Comment: 9 pages, 7 figure
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