2,964 research outputs found
Magnetic-field effects on the in-plane electrical resistivity in the single-crystal LaBaCuO and LaNdSrCuO around : Relating to the field-induced stripe order
Temperature dependence of the in-plane electrical resistivity, , in various magnetic fields has been measured in the single-crystal
LaBaCuO with , 0.10, 0.11 and
LaNdSrCuO with . It has been found that the
superconducting transition curve shows a so-called fan-shape broadening in
magnetic fields for , while it shifts toward the low-temperature side
in parallel with increasing field for and 0.12 where the charge-spin
stripe order is formed at low temperatures. As for , the broadening is
observed in low fields and it changes to the parallel shift in high fields
above 9 T. Moreover, the normal-state value of at low
temperatures markedly increases with increasing field up to 15 T. It is
possible that these pronounced features of are understood in terms of
the magnetic-field-induced stabilization of the stripe order suggested from the
neutron-scattering measurements in the La-214 system. The in
the normal state at low temperatures has been found to be proportional to
ln(1/) for , 0.11 and 0.12. The ln(1/) dependence of is robust even in the stripe-ordered state.Comment: 6 pages, 4 figures, ver. 2 has been accepted for publication in Phys.
Rev.
A novel approach to investigate surface roughness evolution in asymmetric rolling based on three dimensional real surface
Surface roughness affects the friction behaviour, stress distribution and surface quality; moreover this influence is more significant when scaling down the strip size. A novel approach has been proposed to investigate the surface roughness in asymmetric rolling based on Finite Element Analysis (FEA). Evolution of asperity flattening, contact area ratio and surface roughness is investigated under various simulation rolling conditions. The model reviewed numerical solutions for real surfaces with asperities of arbitrary shape and varying size and height distributions. The rolling characterization has also been identified for asymmetric rolling. The difference of change in surface roughness for upper and lower strip surface is large during rolling. The effect of the speed asymmetry factor on strip bending has been established. An increase of the speed asymmetry factor causes an increase in the strip curvature, while the force parameters decrease with increasing asymmetry factor. The speed asymmetric factor influences the strip bending significantly. It is the first attempt to carry out this kind of research in surface roughness based on real surface during asymmetric rolling of thin strip. 2013 Elsevier B.V
Neutron Scattering Study of Temperature-Concentration Phase Diagram of (Cu1-xMgx)GeO3
In doped CuGeO3 systems, such as (Cu1-xZnx)GeO3 and Cu(Ge1-xSix)O3, the
spin-Peierls (SP) ordering (T<Tsp) coexists with the antiferromagnetic (AF)
phase (T<TN<Tsp). Tsp decreases while TN increases with increasing x in low
doping region. For higher x, however, the SP state disappears and only the AF
state remains. These features are common for all the doped CuGeO3 systems so
far studied, indicating the existence of universal T-x phase diagram. Recently,
Masuda et al. carried out comprehensive magnetic susceptibility (chi)
measurements of (Cu1-xMgx)GeO3, in which doping concentration can be controlled
significantly better than the Zn doped systems. They found that TN suddenly
jumps from 3.43 to 3.98K at the critical concentration xc sim 0.023 and that a
drop in chi corresponding to the SP ordering also disappears at x>xc. They thus
concluded that there is a compositional phase boundary between two distinct
magnetic phases. To clarify the nature of two phases, we performed
neutron-scattering measurements on (Cu1-xMgx)GeO3 single crystals with various
x. Analysis of the data at fixed temperature points as a function of doping
concentration has revealed sudden changes of order parameters at the critical
concentration xc=0.027 +- 0.001. At finite temperatures below TN, the drastic
increase of the AF moment takes place at xc. The spin-Peierls order parameter
delta associated with lattice dimerization shows a precipitous decrease at all
temperature below Tsp. However, it goes to zero above xc only at the low
temperature limit.Comment: 9 pages, 9 figure
Synthesis of infinite-layer LaNiO2 films by metal-organic deposition
We report the synthesis of infinite-layer LaNiO2 thin films by metal organic
decomposition. Our work is aimed to synthesize perovskite-like oxides with 3d9
electronic configuration, which is common to high-Tc copper oxides. The 3d9
configuration is very rare in oxides other than cuprates. Ni1+ oxides, even
though Ni1+ is an unusual oxidation state, may be one of very few candidates.
One example of the Ni1+ phases is infinite-layer LaNiO2. The bulk synthesis of
LaNiO2 is difficult, but we demonstrate in this article that the thin-film
synthesis of LaNiO2 by metal organic decomposition is rather easy. This is due
to the advantage of thin films with a large-surface-to-volume ratio, which
makes oxygen diffusion prompt. Resistivity measurements indicate that LaNiO2 is
essentially a metal but unfortunately with no trace of superconductivity yet.Comment: 13 pages, 4 figure
Wilson ratio of a Tomonaga-Luttinger liquid in a spin-1/2 Heisenberg ladder
Using micromechanical force magnetometry, we have measured the magnetization
of the strong-leg spin-1/2 ladder compound (CHN)CuBr at
temperatures down to 45 mK. Low-temperature magnetic susceptibility as a
function of field exhibits a maximum near the critical field H_c at which the
magnon gap vanishes, as expected for a gapped one-dimensional antiferromagnet.
Above H_c a clear minimum appears in the magnetization as a function of
temperature as predicted by theory. In this field region, the susceptibility in
conjunction with our specific heat data yields the Wilson ratio R_W. The result
supports the relation R_W=4K, where K is the Tomonaga-Luttinger-liquid
parameter
Effects of Disorder on the Competition between Antiferromagnetism and Superconductivity
Motivated by the observation of unusual magnetism in Ce_xCu_2Si_2 (), we study the effect of disorder, such as Ce vacancy, on the competition
between superconductivity (SC) and antiferromagnetism (AF) on the basis of the
phenomenological Ginzburg-Landau theory. Assuming that the AF-SC transition is
of first order in clean system, we show that a single impurity in the SC state
can induce staggered magnetization by suppressing the SC around it. For finite
concentration of impurities, the first-order AF-SC boundary in the clean case
is replaced by a finite region where the SC and the induced AF moments coexist
microscopically with spatially varying order parameters. We argue that spin
excitation spectrum in the coexistent state has a dual structure of SC gapped
mode and the low-energy spin-wave mode. In accordance with the emergence of AF
out of SC ground state, the spectral weight will be transferred from the former
mode to the latter, keeping the structure of both modes basically unchanged.Comment: 5 pages, 1 figure, submitted to J. Phys. Soc. Japa
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