280 research outputs found
Geometry-induced reduction of the critical current in superconducting nanowires
Reduction of the critical current in narrow superconducting NbN lines with
sharp and rounded bends with respect to the critical current in straight lines
was studied at different temperatures. We compare our experimental results with
the reduction expected in the framework of the London model and the
Ginsburg-Landau model. We have experimentally found that the reduction is
significantly less than either model predicts. We also show that in our NbN
lines the bends mostly contribute to the reduction of the critical current at
temperatures well below the superconducting transition temperature
Considerable enhancement of the critical current in a superconducting film by magnetized magnetic strip
We show that a magnetic strip on top of a superconducting strip magnetized in
a specified direction may considerably enhance the critical current in the
sample. At fixed magnetization of the magnet we observed diode effect - the
value of the critical current depends on the direction of the transport
current. We explain these effects by a influence of the nonuniform magnetic
field induced by the magnet on the current distribution in the superconducting
strip. The experiment on a hybrid Nb/Co structure confirmed the predicted
variation of the critical current with a changing value of magnetization and
direction of the transport current.Comment: 6 pages, 7 figure
Quantum interference of electrons in Nb_{5-\delta}Te_4 single crystals
The compound () with quasi-one-dimensional
crystal structure undergoes a transition to superconductivity at =0.6--0.9
K. Its electronic transport properties in the normal state are studied in the
temperature range 1.3--270 K and in magnetic fields up to 11 T. The temperature
variation of the resistivity is weak () in the investigated temperature
range. Nonmonotonic behavior of the resistivity is observed which is
characterized by two local maxima at 2 K and 30 K. The temperature
dependence of the resistivity is interpreted as an interplay of weak
localization, weak antilocalization, and electron-electron interaction effects
in the diffusion and the Cooper channel. The temperature dependence of the
dephasing time extracted from the magnetoresistance data is
determined by the electron-phonon interaction. The saturation of in
the low-temperature limit correlates with of the individual crystal and
is ascribed to the scattering on magnetic impurities.Comment: 8 pages, 6 figure
Nonequilibrium phenomena in high Landau levels
Developments in the physics of 2D electron systems during the last decade
have revealed a new class of nonequilibrium phenomena in the presence of a
moderately strong magnetic field. The hallmark of these phenomena is
magnetoresistance oscillations generated by the external forces that drive the
electron system out of equilibrium. The rich set of dramatic phenomena of this
kind, discovered in high mobility semiconductor nanostructures, includes, in
particular, microwave radiation-induced resistance oscillations and
zero-resistance states, as well as Hall field-induced resistance oscillations
and associated zero-differential resistance states. We review the experimental
manifestations of these phenomena and the unified theoretical framework for
describing them in terms of a quantum kinetic equation. The survey contains
also a thorough discussion of the magnetotransport properties of 2D electrons
in the linear response regime, as well as an outlook on future directions,
including related nonequilibrium phenomena in other 2D electron systems.Comment: 60 pages, 41 figure
Electron-Assisted Hopping in Two Dimensions
We have studied the non-ohmic effects in the conductivity of a
two-dimensional system which undergoes the crossover from weak to strong
localization with decreasing electron concentration. When the electrons are
removed from equilibrium with phonons, the hopping conductivity depends only on
the electron temperature. This indicates that the hopping transport in a system
with a large localization length is assisted by electron-electron interactions
rather than by the phonons.Comment: 5 pages, 4 figure
Quantum Size Effect transition in percolating nanocomposite films
We report on unique electronic properties in Fe-SiO2 nanocomposite thin films
in the vicinity of the percolation threshold. The electronic transport is
dominated by quantum corrections to the metallic conduction of the Infinite
Cluster (IC). At low temperature, mesoscopic effects revealed on the
conductivity, Hall effect experiments and low frequency electrical noise
(random telegraph noise and 1/f noise) strongly support the existence of a
temperature-induced Quantum Size Effect (QSE) transition in the metallic
conduction path. Below a critical temperature related to the geometrical
constriction sizes of the IC, the electronic conductivity is mainly governed by
active tunnel conductance across barriers in the metallic network. The high 1/f
noise level and the random telegraph noise are consistently explained by random
potential modulation of the barriers transmittance due to local Coulomb
charges. Our results provide evidence that a lowering of the temperature is
somehow equivalent to a decrease of the metal fraction in the vicinity of the
percolation limit.Comment: 21 pages, 8 figure
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