1,459 research outputs found
The Massive Schwinger Model in a Fast Moving Frame
We present a non-perturbative study of the massive Schwinger model. We use a
Hamiltonian approach, based on a momentum lattice corresponding to a fast
moving reference frame, and equal time quantization.Comment: contribution to Lattice'98 including: 2 style files
(espcrc2.sty,psfig.sty) + text file (LaTeX) + 3 figures (ps) + complete
paper(ps
Kondo effect of a Co atom on Cu(111) in contact with an Fe tip
Single Co atoms, which exhibit a Kondo effect on Cu(111), are contacted with
Cu and Fe tips in a low-temperature scanning tunneling microscope. With Fe
tips, the Kondo effect persists with the Abrikosov-Suhl resonance significantly
broadened. In contrast, for Cu-covered W tips, the resonance width remains
almost constant throughout the tunneling and contact ranges. The distinct
changes of the line width are interpreted in terms of modifications of the Co d
state occupation owing to hybridization with the tip apex atoms.Comment: 4 pages, 3 figure
Understanding and engineering phonon-mediated tunneling into graphene on metal surfaces
Metal-intercalated graphene on Ir(111) exhibits phonon signatures in
inelastic elec- tron tunneling spectroscopy with strengths that depend on the
intercalant. Extraor- dinarily strong graphene phonon signals are observed for
Cs intercalation. Li interca- lation likewise induces clearly discriminable
phonon signatures, albeit less pronounced than observed for Cs. The signal can
be finely tuned by the alkali metal coverage and gradually disappears upon
increasing the junction conductance from tunneling to con- tact ranges. In
contrast to Cs and Li, for Ni-intercalated graphene the phonon signals stay
below the detection limit in all transport ranges. Going beyond the
conventional two-terminal approach, transport calculations provide a
comprehensive understanding of the subtle interplay between the
graphene{electrode coupling and the observation of graphene phonon
spectroscopic signatures
Quantized Conductance of a Single Magnetic Atom
A single Co atom adsorbed on Cu(111) or on ferromagnetic Co islands is
contacted with non-magnetic W or ferromagnetic Ni tips in a scanning tunneling
microscope. When the Co atom bridges two non-magnetic electrodes conductances
of 2e^2/h are found. With two ferromagnetic electrodes a conductance of e^2/h
is observed which may indicate fully spin-polarized transport.Comment: 3 pages, 2 figure
Origin of the large thermoelectric power in oxygen-variable RBaCo_{2}O_{5+x} (R=Gd, Nd)
Thermoelectric properties of GdBaCo_{2}O_{5+x} and NdBaCo_{2}O_{5+x} single
crystals have been studied upon continuous doping of CoO_2 planes with either
electrons or holes. The thermoelectric response and the resistivity behavior
reveal a hopping character of the transport in both compounds, providing the
basis for understanding the recently found remarkable divergence of the Seebeck
coefficient at x=0.5. The doping dependence of the thermoelectric power evinces
that the configurational entropy of charge carriers, enhanced by their spin and
orbital degeneracy, plays a key role in the origin of the large thermoelectric
response in these correlated oxides.Comment: 5 pages, 4 figures, accepted for publication in PR
Formation and structure of calcium carbonate thin films and nanofibers precipitated in the presence of poly(allylamine hydrochloride) and magnesium ions
That the cationic polyelectrolyte poly(allylamine hydrochloride) (PAH) exerts a significant influence on CaCOâ precipitation challenges the idea that only anionic additives have this effect. Here, we show that in common with anionic polyelectrolytes such as poly(aspartic acid), PAH supports the growth of calcite thin films and abundant nanofibers. While investigating the formation of these structures, we also perform the first detailed structural analysis of the nanofibers by transmission electron microscopy (TEM) and selected area electron diffraction. The nanofibers are shown to be principally single crystal, with isolated domains of polycrystallinity, and the single crystal structure is even preserved in regions where the nanofibers dramatically change direction. The formation mechanism of the fibers, which are often hundreds of micrometers long, has been the subject of intense speculation. Our results suggest that they form by aggregation of amorphous particles, which are incorporated into the fibers uniquely at their tips, before crystallizing. Extrusion of polymer during crystallization may inhibit particle addition at the fiber walls and result in local variations in the fiber nanostructure. Finally, we investigate the influence of MgÂČ+ on CaCOâ precipitation in the presence of PAH, which gives thinner and smoother films, together with fibers with more polycrystalline, granular structures
Replacement of hematopoietic system by allogeneic stem cell transplantation in myelofibrosis patients induces rapid regression of bone marrow fibrosis
Bone marrow fibrosis is a hallmark of primary and post ET/PV myelofibrosis. To investigated the impact of replacement of the hematopoietic system in myelofibrosis patients by allogeneic stem cell transplantation on bone marrow fibrosis, we studied bone marrow fibrosis on bone marrow samples from 24 patients with myelofibrosis before and after dose-reduced conditioning followed by allogeneic stem cell transplantation from related or unrelated donor. Using the European Consensus on Grading Bone Marrow Fibrosis, before allografting all patients had advanced fibrosis MF-2 (n = 13) or MF-3 (n = 11). After transplantation, a complete (MF-0) or nearly complete (MF-1) regression of bone marrow fibrosis was seen in 59 % at day +100, in 90 % at day +180, and in 100 % at day +360. No correlation between occurrence of acute graft-versus-host disease, and fibrosis regression on day +180 was seen. We conclude that dose-reduced conditioning, followed by allogeneic stem cell transplantation, resulted in a rapid resolution of bone-marrow fibrosis suggesting the bone marrow fibrogenesis is a highly dynamic rather than static process in patients with myelofibrosis
Two-Mechanism Approach in Thermo-Viscoelasticity with Internal Variables
Two-mechanism (more general: multi-mechanism) models have become an important tool for modeling of complex material behavior. In particular, two-mechanism models have been applied for modeling of ratcheting in metal plasticity as well as of steel behavior in case of phase transformations. The characteristic trait of two-mechanism models is the additive decomposition of the inelastic (i.e., plastic or visco-elastic, e.g.) strain into two parts (sometimes called âmechanismsâ) in the case of small deformations. In comparison with rheological models, there is an interaction between these mechanisms allowing to describe important observable effects. We develop a general visco-elastic two-mechanism model in the framework of the internal-variables approach. As a numerical example, we simulate the movement of a rod having a special visco-elastic behavior. An applied periodic stress with nonzero mean value may lead to a ratcheting effect stemming from the coupling of mechanisms
Estimation of the Compression Modulus of a Technical Rubber via Cyclic Volumetric Compression Tests
In many applications for ïŹnite element (FE) simulations rubber materials are assumed to be nearly incompressible by applying a high ratio between compression modulus and shear modulus. The compression modulus is commonly given as a constant value in FE analysis. In reality this assumption is not fully correct. InïŹuencing factors like the compressibility of the included ïŹller can lead to a notably change of the compression modulus during mechanical loading. The focus of this work is on the estimation of the cyclic evolution of the compression modulus for a technical ethylene propylene diene rubber (EPDM) by using cyclic volumetric compression tests
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