631 research outputs found
Ultrasonic characterization of microstructure in powder metal alloy
The ultrasonic wave propagation characteristics were measured for IN-100, a powder metallurgy alloy used for aircraft engine components. This material was as a model system for testing the feasibility of characterizing the microstructure of a variety of inhomogeneous media including powder metals, ceramics, castings and components. The data were obtained for a frequency range from about 2 to 20 MHz and were statistically averaged over numerous volume elements of the samples. Micrographical examination provided size and number distributions for grain and pore structure. The results showed that the predominant source for the ultrasonic attenuation and backscatter was a dense (approx. 100/cubic mm) distribution of small micropores (approx. 10 micron radius). Two samples with different micropore densities were studied in detail to test the feasibility of calculating from observed microstructural parameters the frequency dependence of the microstructural backscatter in the regime for which the wavelength is much larger than the size of the individual scattering centers. Excellent agreement was found between predicted and observed values so as to demonstrate the feasibility of solving the forward problem. The results suggest a way towards the nondestructive detection and characterization of anomalous distributions of micropores when conventional ultrasonic imaging is difficult. The findings are potentially significant toward the application of the early detection of porosity during the materials fabrication process and after manufacturing of potential sites for stress induced void coalescence leading to crack initiation and subsequent failure
Solitonic Excitations in Linearly Coherent Channels of Bilayer Quantum Hall Stripes
In some range of interlayer distances, the ground state of the
two-dimensional electron gas at filling factor nu =4N+1 with N=0,1,2,... is a
coherent stripe phase in the Hartree-Fock approximation. This phase has
one-dimensional coherent channels that support charged excitations in the form
of pseudospin solitons. In this work, we compute the transport gap of the
coherent striped phase due to the creation of soliton-antisoliton pairs using a
supercell microscopic unrestricted Hartree-Fock approach. We study this gap as
a function of interlayer distance and tunneling amplitude. Our calculations
confirm that the soliton-antisoliton excitation energy is lower than the
corresponding Hartree-Fock electron-hole pair energy. We compare our results
with estimates of the transport gap obtained from a field-theoretic model valid
in the limit of slowly varying pseudospin textures.Comment: 15 pages, 8 figure
Quantum noise detects Floquet topological phases
We study quantum noise in a nonequilibrium, periodically driven, open system
attached to static leads. Using a Floquet Green's function formalism we show,
both analytically and numerically, that local voltage noise spectra can detect
the rich structure of Floquet topological phases unambiguously. Remarkably,
both regular and anomalous Floquet topological bound states can be detected,
and distinguished, via peak structures of noise spectra at the edge around
zero-, half-, and full-drive-frequency. We also show that the topological
features of local noise are robust against moderate disorder. Thus, local noise
measurements are sensitive detectors of Floquet topological phases.Comment: 4.5 pages + supplemental material; v2: improved presentation and new
and updated reference
Dynamical matrix of two-dimensional electron crystals
In a quantizing magnetic field, the two-dimensional electron (2DEG) gas has a
rich phase diagram with broken translational symmetry phases such as Wigner,
bubble, and stripe crystals. In this paper, we derive a method to get the
dynamical matrix of these crystals from a calculation of the density response
function performed in the Generalized Random Phase Approximation (GRPA). We
discuss the validity of our method by comparing the dynamical matrix calculated
from the GRPA with that obtained from standard elasticity theory with the
elastic coefficients obtained from a calculation of the deformation energy of
the crystal.Comment: Revised version published in Phys. Rev. B. 12 pages with 11
postscripts figure
Magnus Force on Quantum Hall Skyrmions and Vortices
We have discussed here the Magnus force acting on the vortices and skyrmions
in the quantum Hall systems. We have found that it is generated by the
chirality of the system which is associated with the Berry phase and is same
for both the cases.Comment: 5 page
Bag Formation in Quantum Hall Ferromagnets
Charged skyrmions or spin-textures in the quantum Hall ferromagnet at filling
factor nu=1 are reinvestigated using the Hartree-Fock method in the lowest
Landau level approximation. It is shown that the single Slater determinant with
the minimum energy in the unit charge sector is always of the hedgehog form. It
is observed that the magnetization vector's length deviates locally from unity,
i.e. a bag is formed which accommodates the excess charge. In terms of a
gradient expansion for extended spin-textures a novel O(3) type of effective
action is presented, which takes bag formation into account.Comment: 13 pages, 3 figure
Theory of Activated Transport in Bilayer Quantum Hall Systems
We analyze the transport properties of bilayer quantum Hall systems at total
filling factor in drag geometries as a function of interlayer bias, in
the limit where the disorder is sufficiently strong to unbind meron-antimeron
pairs, the charged topological defects of the system. We compute the typical
energy barrier for these objects to cross incompressible regions within the
disordered system using a Hartree-Fock approach, and show how this leads to
multiple activation energies when the system is biased. We then demonstrate
using a bosonic Chern-Simons theory that in drag geometries, current in a
single layer directly leads to forces on only two of the four types of merons,
inducing dissipation only in the drive layer. Dissipation in the drag layer
results from interactions among the merons, resulting in very different
temperature dependences for the drag and drive layers, in qualitative agreement
with experiment.Comment: 4 pages, 2 figure
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