2,535 research outputs found
Hybridization at superconductor-semiconductor interfaces
Hybrid superconductor-semiconductor devices are currently one of the most
promising platforms for realizing Majorana zero modes. Their topological
properties are controlled by the band alignment of the two materials, as well
as the electrostatic environment, which are currently not well understood.
Here, we pursue to fill in this gap and address the role of band bending and
superconductor-semiconductor hybridization in such devices by analyzing a gated
single Al-InAs interface using a self-consistent Schrodinger-Poisson approach.
Our numerical analysis shows that the band bending leads to an interface
quantum well, which localizes the charge in the system near the
superconductor-semiconductor interface. We investigate the hybrid band
structure and analyze its response to varying the gate voltage and thickness of
the Al layer. This is done by studying the hybridization degrees of the
individual subbands, which determine the induced pairing and effective
-factors. The numerical results are backed by approximate analytical
expressions which further clarify key aspects of the band structure. We find
that one can obtain states with strong superconductor-semiconductor
hybridization at the Fermi energy, but this requires a fine balance of
parameters, with the most important constraint being on the width of the Al
layer. In fact, in the regime of interest, we find an almost periodic
dependence of the hybridization degree on the Al width, with a period roughly
equal to the thickness of an Al monolayer. This implies that disorder and shape
irregularities, present in realistic devices, may play an important role for
averaging out this sensitivity and, thus, may be necessary for stabilizing the
topological phase.Comment: 10 Figures. 16 pages. Published versio
Simulating Gyrokinetic Microinstabilities in Stellarator Geometry with GS2
The nonlinear gyrokinetic code GS2 has been extended to treat
non-axisymmetric stellarator geometry. Electromagnetic perturbations and
multiple trapped particle regions are allowed. Here, linear, collisionless,
electrostatic simulations of the quasi-axisymmetric, three-field period
National Compact Stellarator Experiment (NCSX) design QAS3-C82 have been
successfully benchmarked against the eigenvalue code FULL. Quantitatively, the
linear stability calculations of GS2 and FULL agree to within ~10%.Comment: Submitted to Physics of Plasmas. 9 pages, 14 figure
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Consistent Estimation of Time-Varying Loadings in High-Dimensional Factor Models
In this paper, we develop a two-step maximum likelihood estimator of time-varying loadings in high-dimensional factor models. We specify the loadings to evolve as stationary vector autoregressions (VAR) and show that consistent estimates of the loadings parameters can be obtained. In the first step, principal components are extracted from the data to formfactor estimates. In the second step, the parameters of the loadings VARs are estimated as a set of linear regression models with time-varying coefficients. We document the finite-sample properties of the maximum likelihood estimator through an extensive simulation study and illustrate the empirical relevance of the time-varying loadings structure using a large quarterly dataset for the US economy
Dynamics of grain ejection by sphere impact on a granular bed
The dynamics of grain ejection consecutive to a sphere impacting a granular
material is investigated experimentally and the variations of the
characteristics of grain ejection with the control parameters are
quantitatively studied. The time evolution of the corona formed by the ejected
grains is reported, mainly in terms of its diameter and height, and favourably
compared with a simple ballistic model. A key characteristic of the granular
corona is that the angle formed by its edge with the horizontal granular
surface remains constant during the ejection process, which again can be
reproduced by the ballistic model. The number and the kinetic energy of the
ejected grains is evaluated and allows for the calculation of an effective
restitution coefficient characterizing the complex collision process between
the impacting sphere and the fine granular target. The effective restitution
coefficient is found to be constant when varying the control parameters.Comment: 9 page
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Balancing competing policy demands: the case of sustainable public sector food procurement.
A focus on market-based green growth strategies to pursue sustainability goals neglects the pursuit of understanding how human health is interwoven with the health of eco-systems to deliver sustainability goals. The article argues that clarifying the difference between green and sustainable public sector food procurement, with political continuity that supports and enables policymakers and practitioners to take an incremental approach to change, makes an important contribution to delivering more sustainable food systems and better public health nutrition. Five European case studies demonstrate the reality of devising and implementing innovative approaches to sustainable public sector food procurement and the effects of cultural and political framings. How legislation is enacted at the national level and interpreted at the local level is a key driver for sustainable procurement. Transition is dependent on political will and leadership and an infrastructure that can balance the economic, environmental and social drivers to effect change. The development of systems and indicators to measure change, reforms to EU directives on procurement, and the relationship between green growth strategies and sustainable diets are also discussed. The findings show the need to explore how consistent definitions for green public procurement and sustainable public procurement can be refined and standardized in order to support governments at all levels in reviewing and analyzing their current food procurement strategies and practices to improve sustainability
Kinetic hindrance during the initial oxidation of Pd(100) at ambient pressures
The oxidation of the Pd(100) surface at oxygen pressures in the 10^-6 to 10^3
mbar range and temperatures up to 1000 K has been studied in-situ by surface
x-ray diffraction (SXRD). The results provide direct structural information on
the phases present in the surface region and on the kinetics of the oxide
formation. Depending on the (T,p) environmental conditions we either observe a
thin sqrt(5) x sqrt(5) R27 surface oxide or the growth of a rough, poorly
ordered bulk oxide film of PdO predominantly with (001) orientation. By either
comparison to the surface phase diagram from first-principles atomistic
thermodynamics or by explicit time-resolved measurements we identify a strong
kinetic hindrance to the bulk oxide formation even at temperatures as high as
675 K.Comment: 4 pages including 4 figures, Related publications can be found at
http://www.fhi-berlin.mpg.de/th/paper.htm
Room temperature structure and energetics of water-hydroxyl layers on Pt(111)
The interactions between water and hydroxyl species on Pt(111) surfaces have
been intensely investigated due to their importance to fuel cell
electrocatalysis. Here we present a room temperature molecular dynamics study
of their structure and energetics using an ensemble of neural network
potentials, which allow us to obtain unprecedented statistical sampling. We
first study the energetics of hydroxyl formation, where we find a near-linear
adsorption energy profile, which exhibits a soft and gradual increase in the
differential adsorption energy at high hydroxyl coverages. This is strikingly
different from the predictions of the conventional bilayer model, which
displays a kink at 1/3ML OH coverage indicating a sizeable jump in differential
adsorption energy, but within the statistical uncertainty of previously
reported ab initio molecular dynamics studies. We then analyze the structure of
the interface, where we provide evidence for the water-OH/Pt(111) interface
being hydrophobic at high hydroxyl coverages. We furthermore explain the
observed adsorption energetics by analyzing the hydrogen bonding in the
water-hydroxyl adlayers, where we argue that the increase in differential
adsorption energy at high OH coverage can be explained by a reduction in the
number of hydrogen bonds from the adsorbed water molecules to the hydroxyls
The role of E1-E2 interplay in multiphonon Coulomb excitation
In this work we study the problem of a charged particle, bound in a
harmonic-oscillator potential, being excited by the Coulomb field from a fast
charged projectile. Based on a classical solution to the problem and using the
squeezed-state formalism we are able to treat exactly both dipole and
quadrupole Coulomb field components. Addressing various transition amplitudes
and processes of multiphonon excitation we study different aspects resulting
from the interplay between E1 and E2 fields, ranging from classical dynamic
polarization effects to questions of quantum interference. We compare exact
calculations with approximate methods. Results of this work and the formalism
we present can be useful in studies of nuclear reaction physics and in atomic
stopping theory.Comment: 10 pages, 6 figure
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