1,000 research outputs found
GHz sandwich strip inductors based on Fe-N Films
Planar strip inductors consisting of two Fe-N films enclosing a conducting
film made of Cu, were fabricated on oxidized Si substrates. The inductors were
1mm long, 2 to 100 um wide, with layers of thickness ~0.1 um for the magnetic
films and ~0.5 um for the conductor. The soft (Hc=4-8 Oe) magnetic layers were
biased during impedance measurement by applying an external field along the
strip length thereby facilitating the transverse susceptibility configuration.
Biased strips exhibited 70 to 100% inductance enhancement at 1GHz with quality
factors Q=4.5 to 3, respectively. The magnetic contribution to the total flux
in the narrow devices was less than predicted theoretically, which was
attributed to hardening of the magnetic material at the edges of the strip,
where the deposition was close to 60 degree incidence. Test films were
fabricated on tilted substrates and found to develop a very high anisotropy (up
to 1 kOe) for deposition angles larger than 30 degrees. Optimizing the flux
closure at the strip edges and using thicker conductor layers is essential for
further improving the performance of sandwich strip inductors.Comment: 18 pages, 9 figure
Coulomb Blockade and Coherent Single-Cooper-Pair Tunneling in Single Josephson Junctions
We have measured the current-voltage characteristics of small-capacitance
single Josephson junctions at low temperatures (T < 0.04 K), where the strength
of the coupling between the single junction and the electromagnetic environment
was controlled with one-dimensional arrays of dc SQUIDs. We have clearly
observed Coulomb blockade of Cooper-pair tunneling and even a region of
negative differential resistance, when the zero-bias resistance of the SQUID
arrays is much higher than the quantum resistance h/e^2 = 26 kohm. The negative
differential resistance is evidence of coherent single-Cooper-pair tunneling in
the single Josephson junction.Comment: RevTeX, 4 pages with 6 embedded figure
Single-electron transistors in electromagnetic environments
The current-voltage (I-V) characteristics of single-electron transistors
(SETs) have been measured in various electromagnetic environments. Some SETs
were biased with one-dimensional arrays of dc superconducting quantum
interference devices (SQUIDs). The purpose was to provide the SETs with a
magnetic-field-tunable environment in the superconducting state, and a
high-impedance environment in the normal state. The comparison of SETs with
SQUID arrays and those without arrays in the normal state confirmed that the
effective charging energy of SETs in the normal state becomes larger in the
high-impedance environment, as expected theoretically. In SETs with SQUID
arrays in the superconducting state, as the zero-bias resistance of the SQUID
arrays was increased to be much larger than the quantum resistance R_K = h/e^2
= 26 kohm, a sharp Coulomb blockade was induced, and the current modulation by
the gate-induced charge was changed from e periodic to 2e periodic at a bias
point 0<|V|<2D_0/e, where D_0 is the superconducting energy gap. The author
discusses the Coulomb blockade and its dependence on the gate-induced charge in
terms of the single Josephson junction with gate-tunable junction capacitance.Comment: 8 pages with 10 embedded figures, RevTeX4, published versio
Quantum Effects in Small-Capacitance Single Josephson Junctions
We have measured the current-voltage (I-V) characteristics of
small-capacitance single Josephson junctions at low temperatures (T=0.02-0.6
K), where the strength of the coupling between the single junction and the
electromagnetic environment was controlled with one-dimensional arrays of dc
SQUIDs. The single-junction I-V curve is sensitive to the impedance of the
environment, which can be tuned IN SITU. We have observed Coulomb blockade of
Cooper-pair tunneling and even a region of negative differential resistance,
when the zero-bias resistance R_0' of the SQUID arrays is much higher than the
quantum resistance R_K = h/e^2 = 26 kohm. The negative differential resistance
is evidence of coherent single-Cooper-pair tunneling within the theory of
current-biased single Josephson junctions. Based on the theory, we have
calculated the I-V curves numerically in order to compare with the experimental
ones at R_0' >> R_K. The numerical calculation agrees with the experiments
qualitatively. We also discuss the R_0' dependence of the
single-Josephson-junction I-V curve in terms of the superconductor-insulator
transition driven by changing the coupling to the environment.Comment: 11 pages with 14 embedded figures, RevTeX4, final versio
Interpreting motion and force for narrow-band intermodulation atomic force microscopy
Intermodulation atomic force microscopy (ImAFM) is a mode of dynamic atomic
force microscopy that probes the nonlinear tip-surface force by measurement of
the mixing of multiple tones in a frequency comb. A high cantilever
resonance and a suitable drive comb will result in tip motion described by a
narrow-band frequency comb. We show by a separation of time scales, that such
motion is equivalent to rapid oscillations at the cantilever resonance with a
slow amplitude and phase or frequency modulation. With this time domain
perspective we analyze single oscillation cycles in ImAFM to extract the
Fourier components of the tip-surface force that are in-phase with tip motion
() and quadrature to the motion (). Traditionally, these force
components have been considered as a function of the static probe height only.
Here we show that and actually depend on both static probe height
and oscillation amplitude. We demonstrate on simulated data how to reconstruct
the amplitude dependence of and from a single ImAFM measurement.
Furthermore, we introduce ImAFM approach measurements with which we reconstruct
the full amplitude and probe height dependence of the force components
and , providing deeper insight into the tip-surface interaction. We
demonstrate the capabilities of ImAFM approach measurements on a polystyrene
polymer surface.Comment: 12 pages, 7 figure
Enhanced spin accumulation in a superconductor
A lateral array of ferromagnetic tunnel junctions is used to inject and
detect non-equilibrium quasi-particle spin distribution in a superconducting
strip made of Al. The strip width and thickness is kept below the quasi
particle spin diffusion length in Al. Non-local measurements in multiple
parallel and antiparallel magnetic states of the detectors are used to in-situ
determine the quasi-particle spin diffusion length. A very large increase in
the spin accumulation in the superconducting state compared to that in the
normal state is observed and is attributed to a diminishing of the
quasi-particle population by opening of the gap below the transition
temperature.Comment: 6 pages, 4 figures; accepted for publication in Journal of Applied
Physic
Who Owns This Text?: Plagiarism, Authorship, and Disciplinary Cultures
Carol Haviland, Joan Mullin, and their collaborators report on a three-year interdisciplinary interview project on the subject of plagiarism, authorship, and property, and how these are conceived across different fields. The study investigated seven different academic fields to discover disciplinary conceptions of what types of scholarly production count as owned. Less a research report than a conversation, the book offers a wide range of ideas, and the chapters here will provoke discussion on scholarly practice relating to intellectual property, plagiarism, and authorship---and to how these matters are conveyed to students. Although these authors find a good deal of consensus in regard to the ethical issues of plagiarism, they document a surprising variety of practice on the subject of what ownership looks like from one discipline to another. And they discover that students are not often instructed in the conventions of their major field.https://digitalcommons.usu.edu/usupress_pubs/1025/thumbnail.jp
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