In this paper we present the results of a systematic study on the magnetic field penetration depth of superconducting niobium thin films. The films of thicknesses ranging from 8 to 300 nm were deposited on a Si substrate by dc magnetron sputtering. The values of the penetration depth ͑0͒ were obtained from the measurements of the effective microwave surface impedance by employing a sapphire resonator technique. Additionally, for the films of thickness smaller than 20 nm, the absolute values of ͑0͒ were determined by a microwave transmission method. We found that the reduction of the film thickness below 50 nm leads to a significant increase of the magnetic field penetration depth from about 80 nm for 300 nm thick film up to 230 nm for a 8 nm thick film. The dependence of the penetration depth on film thickness is described well by taking into account the experimental dependences of the critical temperature and residual resistivity on the thickness of the niobium films. Structural disordering of the films and suppression of superconductivity due to the proximity effect are considered as mechanisms responsible for the increase of the penetration depth in ultrathin films.
Abstract----The temperature dependence of the real part of the microwave complex conductivity at 17.9 GHz obtained from surface impedance measurements of two c-axis oriented MgB 2 thin films reveals a pronounced maximum at a temperature around 0.6 times the critical temperature. Calculations in the frame of a two-band model based on BardeenCooper-Schrieffer (BCS) theory suggest that this maximum corresponds to an anomalous coherence peak resembling the two-gap nature of MgB 2 . Our model assumes there is no interband impurity scattering and a weak interband pairing interaction, as suggested by bandstructure calculations. In addition, the observation of a coherence peak indicates that the π-band is in the dirty limit and dominates the total conductivity of our films.
The dependences of magnetic field penetration depth at zero temperature
λ(0), microwave surface
resistance Rs and
π-band energy gap at
zero temperature Δπ(0)
on the normal-state resistivity right above the critical temperature,
ρ0, were
studied for MgB2
thin films prepared by different techniques by employing a sapphire
resonator technique. We found that the zero-temperature penetration depth
λ(0)
data could be well fitted by yielding a London penetration depth
λL of 34.5 nm,
where ξ0
is the coherence length, and is the mean free path determined from
ρ0. The surface
resistance Rs
at 15 and 20 K increases roughly linearly with
ρ0. The observed
increase of Δπ(0)
with ρ0 and the
decrease of Tc
indicate the expected effects of interband impurity scattering within an extended BCS approach. The low
values of Rs
and λ(0)
in conjunction with the large coherence length for epitaxial films are potentially attractive
for applications in electronics and microwave technology.
The paper reports on finding the effect of a strong change in the microwave losses in an HTSbased coplanar waveguide (CPW) at certain values of the input power P in and direct current I dc .CPW on the basis of 150 nm thick YBa 2 Cu 3 O 7-δ epitaxial film on a single crystal MgO substrate was studied experimentally. A sharp and reversible transition of the CPW into a strongly dissipative state at the certain meanings of P in and I dc depending on temperature was observed.Apparently the effect can be explained by self-heating of HTS structure caused by magnetic flux flow under the joint influence of MW and DC.Since discovery of high-temperature superconductors (HTS) in 1986 [1] a lot of attention has been given to studying nonlinear properties of HTS in microwave (MW) fields [2][3][4].
Studies of biochemical liquids require precise determination of their complex permittivity. We developed a microwave characterization technique on the basis of a high-quality whispering-gallery mode (WGM) sapphire resonator with a microfluidic channel filled with the liquid under test. A novel approach allows obtaining the complex permittivity of biochemical liquids of sub-microliter/nanoliter volumes with high accuracy. The method is based on a special procedure of analysis of the interaction of electromagnetic field with liquid in a WGM microfluidic resonator and measurements of both the WGM resonance frequency shift and the change of the inverse quality factor. The approach is successfully applied to obtain the complex permittivity in the Ka-band of glucose, albumin bovine serum, lactalbumin, and cytochrome C aqueous solutions using the developed microwave technique.
Magnetic, electric, and radioprotector properties of hybrid nanocomposites of Fe3O4 nanoparticles with and without a shell of polyaniline (PANI), which is doped with dodecylbenzenesulfonic acid (DBSA), dispersed in polyvinylidene fluoride (PVDF) matrix have been studied. It has been found that the presence of PANI–DBSA as a separate filler in the ternary nanocomposite film, which also contains as another filler the core–shell Fe3O4/PANI–DBSA nanoparticles, facilitates dispersion of the magnetic filler due to the improvement of its compatibility with the PVDF matrix. This leads both to the decrease in coefficient of squareness of the hysteresis loop and to the increase in electromagnetic energy (EME) absorption of the nanocomposite film.
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