6,788 research outputs found
Sample-specific and Ensemble-averaged Magnetoconductance of Individual Single-Wall Carbon Nanotubes
We discuss magnetotransport measurements on individual single-wall carbon
nanotubes with low contact resistance, performed as a function of temperature
and gate voltage. We find that the application of a magnetic field
perpendicular to the tube axis results in a large magnetoconductance of the
order of e^2/h at low temperature. We demonstrate that this magnetoconductance
consists of a sample-specific and of an ensemble-averaged contribution, both of
which decrease with increasing temperature. The observed behavior resembles
very closely the behavior of more conventional multi-channel mesoscopic wires,
exhibiting universal conductance fluctuations and weak localization. A
theoretical analysis of our experiments will enable to reach a deeper
understanding of phase-coherent one-dimensional electronic motion in SWNTs.Comment: Replaced with published version. Minor changes in tex
Spin-dependent Quantum Interference in Single-Wall Carbon Nanotubes with Ferromagnetic Contacts
We report the experimental observation of spin-induced magnetoresistance in
single-wall carbon nanotubes contacted with high-transparency ferromagnetic
electrodes. In the linear regime the spin-induced magnetoresistance oscillates
with gate voltage in quantitative agreement with calculations based on a
Landauer-Buttiker model for independent electrons. Consistent with this
interpretation, we find evidence for bias-induced oscillation in the
spin-induced magnetoresistance signal on the scale of the level spacing in the
nanotube. At higher bias, the spin-induced magnetoresistance disappears because
of a sharp decrease in the effective spin-polarization injected from the
ferromagnetic electrodes.Comment: Replaced with published versio
Controlling spin in an electronic interferometer with spin-active interfaces
We consider electronic current transport through a ballistic one-dimensional
quantum wire connected to two ferromagnetic leads. We study the effects of the
spin-dependence of interfacial phase shifts (SDIPS) acquired by electrons upon
scattering at the boundaries of the wire. The SDIPS produces a spin splitting
of the wire resonant energies which is tunable with the gate voltage and the
angle between the ferromagnetic polarizations. This property could be used for
manipulating spins. In particular, it leads to a giant magnetoresistance effect
with a sign tunable with the gate voltage and the magnetic field applied to the
wire.Comment: 5 pages, 3 figures. to be published in Europhysics Letter
Coherent States Formulation of Polymer Field Theory
We introduce a stable and efficient complex Langevin (CL) scheme to enable
the first numerical simulations of the coherent-states (CS) formulation of
polymer field theory. In contrast with Edwards' well known auxiliary-field (AF)
framework, the CS formulation does not contain an embedded non-linear,
non-local functional of the auxiliary fields, and the action of the field
theory has a fully explicit, finite-order and semi-local polynomial character.
In the context of a polymer solution model, we demonstrate that the new CS-CL
dynamical scheme for sampling fluctuations in the space of coherent states
yields results in good agreement with now-standard AF simulations. The
formalism is potentially applicable to a broad range of polymer architectures
and may facilitate systematic generation of trial actions for use in
coarse-graining and numerical renormalization-group studies.Comment: 14pages 8 figure
Parametrical optimization of laser surface alloyed NiTi shape memory alloy with Co and Nb by the Taguchi method
Different high-purity metal powders were successfully alloyed on to a nickel titanium (NiTi) shape memory alloy (SMA) with a 3 kW carbon dioxide (CO2) laser system. In order to produce an alloyed layer with complete penetration and acceptable composition profile, the Taguchi approach was used as a statistical technique for optimizing selected laser processing parameters. A systematic study of laser power, scanning velocity, and pre-paste powder thickness was conducted. The signal-to-noise ratios (S/N) for each control factor were calculated in order to assess the deviation from the average response. Analysis of variance (ANOVA) was carried out to understand the significance of process variables affecting the process effects. The Taguchi method was able to determine the laser process parameters for the laser surface alloying technique with high statistical accuracy and yield a laser surface alloying technique capable of achieving a desirable dilution ratio. Energy dispersive spectrometry consistently showed that the per cent by weight of Ni was reduced by 45 per cent as compared with untreated NiTi SMA when the Taguchi-determined laser processing parameters were employed, thus verifying the laser's processing parameters as optimum
On Measuring Fairness in Generative Models
Recently, there has been increased interest in fair generative models. In
this work, we conduct, for the first time, an in-depth study on fairness
measurement, a critical component in gauging progress on fair generative
models. We make three contributions. First, we conduct a study that reveals
that the existing fairness measurement framework has considerable measurement
errors, even when highly accurate sensitive attribute (SA) classifiers are
used. These findings cast doubts on previously reported fairness improvements.
Second, to address this issue, we propose CLassifier Error-Aware Measurement
(CLEAM), a new framework which uses a statistical model to account for
inaccuracies in SA classifiers. Our proposed CLEAM reduces measurement errors
significantly, e.g., 4.98% 0.62% for StyleGAN2 w.r.t. Gender.
Additionally, CLEAM achieves this with minimal additional overhead. Third, we
utilize CLEAM to measure fairness in important text-to-image generator and
GANs, revealing considerable biases in these models that raise concerns about
their applications. Code and more resources:
https://sutd-visual-computing-group.github.io/CLEAM/.Comment: Accepted in NeurIPS2
High-capacity quantum secure direct communication based on quantum hyperdense coding with hyperentanglement
We present a quantum hyperdense coding protocol with hyperentanglement in
polarization and spatial-mode degrees of freedom of photons first and then give
the details for a quantum secure direct communication (QSDC) protocol based on
this quantum hyperdense coding protocol. This QSDC protocol has the advantage
of having a higher capacity than the quantum communication protocols with a
qubit system. Compared with the QSDC protocol based on superdense coding with
-dimensional systems, this QSDC protocol is more feasible as the preparation
of a high-dimension quantum system is more difficult than that of a two-level
quantum system at present.Comment: 5 pages, 2 figur
Impact of Uniaxial Pressure on Structural and Magnetic Phase Transitions in Electron-Doped Iron Pnictides
We use neutron resonance spin echo and Larmor diffraction to study the effect
of uniaxial pressure on the tetragonal-to-orthorhombic structural () and
antiferromagnetic (AF) phase transitions in iron pnictides
BaFeNiAs (), SrFeNiAs,
and BaFe(AsP). In antiferromagnetically ordered
BaFeNiAs and SrFeNiAs with and
(), a uniaxial pressure necessary to detwin the sample also
increases , smears out the structural transition, and induces an
orthorhombic lattice distortion at all temperatures. By comparing temperature
and doping dependence of the pressure induced lattice parameter changes with
the elastoresistance and nematic susceptibility obtained from transport and
ultrasonic measurements, we conclude that the in-plane resistivity anisotropy
found in the paramagnetic state of electron underdoped iron pnictides depends
sensitively on the nature of the magnetic phase transition and a strong
coupling between the uniaxial pressure induced lattice distortion and
electronic nematic susceptibility.Comment: 18 pages, 15 figure
A Simultaneous Quantum Secure Direct Communication Scheme between the Central Party and Other M Parties
We propose a simultaneous quantum secure direct communication scheme between
one party and other three parties via four-particle GHZ states and swapping
quantum entanglement. In the scheme, three spatially separated senders, Alice,
Bob and Charlie, transmit their secret messages to a remote receiver Diana by
performing a series local operations on their respective particles according to
the quadripartite stipulation. From Alice, Bob, Charlie and Diana's Bell
measurement results, Diana can infer the secret messages. If a perfect quantum
channel is used, the secret messages are faithfully transmitted from Alice, Bob
and Charlie to Diana via initially shared pairs of four-particle GHZ states
without revealing any information to a potential eavesdropper. As there is no
transmission of the qubits carrying the secret message in the public channel,
it is completely secure for the direct secret communication. This scheme can be
considered as a network of communication parties where each party wants to
communicate secretly with a central party or server.Comment: 4 pages, no figur
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