1,997 research outputs found
Three-dimensional in vitro models of prostate cancer
Issued as final reportGeorgia Cancer Coalitio
Enhancement of parametric pumping due to Andreev reflection
We report properties of parametric electron pumping in the presence of a
superconducting lead. Due to a constructive interference between the direct
reflection and the multiple Andreev reflection, the pumped current is greatly
enhanced. For both quantum point contacts and double barrier structures at
resonance, we obtain exact solutions in the weak pumping regime showing that
, which should be compared with the result of conductance
. Numerical results are also provided for the strong pumping
regime showing interesting Andreev assisted pumping behaviour
Electron transport through Al-ZnO-Al: an {\it ab initio} calculation
The electron transport properties of ZnO nano-wires coupled by two aluminium
electrodes were studied by {\it ab initio} method based on non-equilibrium
Green's function approach and density functional theory. A clearly rectifying
current-voltage characteristics was observed. It was found that the contact
interfaces between Al-O and Al-Zn play important roles in the charge transport
at low bias voltage and give very asymmetric I-V characteristics. When the bias
voltage increases, the negative differential resistance occurs at negative bias
voltage. The charge accumulation was calculated and its behavior was found to
be well correlated with the I-V characteristics. We have also calculated the
electrochemical capacitance which exhibits three plateaus at different bias
voltages which may have potential device application.Comment: 10 pages, 6 figure
On representing signals using only timing information
It is well known that only a special class of bandpass signals, called real-zero (RZ) signals can be uniquely represented (up to a scale factor) by their zero crossings, i.e., the time instants at which the signals change their sign. However, it is possible to invertibly map arbitrary bandpass signals into RZ signals, thereby, implicitly represent the bandpass signal using the mapped RZ signal’s zero crossings. This mapping is known as real-zero conversion (RZC). In this paper a class of novel signal-adaptive RZC algorithms is proposed. Specifically, algorithms that are analogs of well-known adaptive filtering methods to convert an arbitrary bandpass signal into other signals, whose zero crossings contain sufficient information to represent the bandpass signal’s phase and envelope are presented. Since the proposed zero crossings are not those of the original signal, but only indirectly related to it, they are called hidden or covert zero crossings (CoZeCs). The CoZeCs-based representations are developed first for analytic signals, and then extended to real-valued signals. Finally, the proposed algorithms are used to represent synthetic signals and speech signals processed through an analysis filter bank, and it is shown that they can be reconstructed given the CoZeCs. This signal representation has potential in many speech applications
Engineering Photon Delocalization in a Rabi Dimer with a Dissipative Bath
A Rabi dimer is used to model a recently reported circuit quantum
electrodynamics system composed of two coupled transmission-line resonators
with each coupled to one qubit. In this study, a phonon bath is adopted to
mimic the multimode micromechanical resonators and is coupled to the qubits in
the Rabi dimer. The dynamical behavior of the composite system is studied by
the Dirac-Frenkel time-dependent variational principle combined with the
multiple Davydov D ans\"{a}tze. Initially all the photons are pumped into
the left resonator, and the two qubits are in the down state coupled with the
phonon vacuum. In the strong qubit-photon coupling regime, the photon dynamics
can be engineered by tuning the qubit-bath coupling strength and
photon delocalization is achieved by increasing . In the absence of
dissipation, photons are localized in the initial resonator. Nevertheless, with
moderate qubit-bath coupling, photons are delocalized with quasiequilibration
of the photon population in two resonators at long times. In this case, high
frequency bath modes are activated by interacting with depolarized qubits. For
strong dissipation, photon delocalization is achieved via frequent
photon-hopping within two resonators and the qubits are suppressed in their
initial down state.Comment: 11 pages, 11 figure
Wide & deep learning for spatial & intensity adaptive image restoration
Most existing deep learning-based image restoration methods usually aim to
remove degradation with uniform spatial distribution and constant intensity,
making insufficient use of degradation prior knowledge. Here we bootstrap the
deep neural networks to suppress complex image degradation whose intensity is
spatially variable, through utilizing prior knowledge from degraded images.
Specifically, we propose an ingenious and efficient multi-frame image
restoration network (DparNet) with wide & deep architecture, which integrates
degraded images and prior knowledge of degradation to reconstruct images with
ideal clarity and stability. The degradation prior is directly learned from
degraded images in form of key degradation parameter matrix, with no
requirement of any off-site knowledge. The wide & deep architecture in DparNet
enables the learned parameters to directly modulate the final restoring
results, boosting spatial & intensity adaptive image restoration. We
demonstrate the proposed method on two representative image restoration
applications: image denoising and suppression of atmospheric turbulence effects
in images. Two large datasets, containing 109,536 and 49,744 images
respectively, were constructed to support our experiments. The experimental
results show that our DparNet significantly outperform SoTA methods in
restoration performance and network efficiency. More importantly, by utilizing
the learned degradation parameters via wide & deep learning, we can improve the
PSNR of image restoration by 0.6~1.1 dB with less than 2% increasing in model
parameter numbers and computational complexity. Our work suggests that degraded
images may hide key information of the degradation process, which can be
utilized to boost spatial & intensity adaptive image restoration
Universal quantized spin-Hall conductance fluctuation in graphene
We report a theoretical investigation of quantized spin-Hall conductance
fluctuation of graphene devices in the diffusive regime. Two graphene models
that exhibit quantized spin-Hall effect (QSHE) are analyzed. Model-I is with
unitary symmetry under an external magnetic field but with zero
spin-orbit interaction, . Model-II is with symplectic symmetry where
B=0 but . Extensive numerical calculations indicate that the two
models have exactly the same universal QSHE conductance fluctuation value
regardless of the symmetry. Qualitatively different from the
conventional charge and spin universal conductance distributions, in the
presence of edge states the spin-Hall conductance shows an one-sided log-normal
distribution rather than a Gaussian distribution. Our results strongly suggest
that the quantized spin-Hall conductance fluctuation belongs to a new
universality class
A comparative study on damage analysis between gaussian and non-gaussian random vibration
Vibratory fatigue has been indicated to be one of the most frequently encountered problems in engineering practice. And it is inevitable that the mechanical components of machine are excited by random signals. Most of the random vibrations in nature contain non-Gaussian components. In order to reduce the failure and economic losses which is caused by vibration, random vibration testing is usually conducted in laboratory to verify whether the components can survive a particular random vibration or to identify weaknesses of items. In this paper, the vibratory fatigue damages of Gaussian random signals and non-Gaussian random signals to a particular system are discussed. The process and difference are illustrated by using a case study
Shot noise of spin current and spin transfer torque
We report the theoretical investigation of noise spectrum of spin current and
spin transfer torque for non-colinear spin polarized transport in a spin-valve
device which consists of normal scattering region connected by two
ferromagnetic electrodes. Our theory was developed using non-equilibrium
Green's function method and general non-linear and
relations were derived as a function of angle between magnetization of
two leads. We have applied our theory to a quantum dot system with a resonant
level coupled with two ferromagnetic electrodes. It was found that for the MNM
system, the auto-correlation of spin current is enough to characterize the
fluctuation of spin current. For a system with three ferromagnetic layers,
however, both auto-correlation and cross-correlation of spin current are needed
to characterize the noise spectrum of spin current. Furthermore, the spin
transfer torque and the torque noise were studied for the MNM system. For a
quantum dot with a resonant level, the derivative of spin torque with respect
to bias voltage is proportional to when the system is far away
from the resonance. When the system is near the resonance, the spin transfer
torque becomes non-sinusoidal function of . The derivative of noise
spectrum of spin transfer torque with respect to the bias voltage
behaves differently when the system is near or far away from the resonance.
Specifically, the differential shot noise of spin transfer torque is a
concave function of near the resonance while it becomes convex
function of far away from resonance. For certain bias voltages, the
period becomes instead of . For small , it
was found that the differential shot noise of spin transfer torque is very
sensitive to the bias voltage and the other system parameters.Comment: 15pages, 6figure
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