38,697 research outputs found
The electromagnetic form factors of the proton in the timelike region
The reactions ppbar -> e+e- and e+e- -> ppbar are analyzed in the
near-threshold region. Specific emphasis is put on the role played by the
interaction in the initial- or final antinucleon-nucleon state which is taken
into account rigorously. For that purpose a recently published NNbar potential
derived within chiral effective field theory and fitted to results of a new
partial-wave analysis of ppbar scattering data is employed. Our results provide
strong support for the conjecture that the pronounced energy dependence of the
e+e- ppbar cross section, seen in pertinent experiments, is primarily due
to the ppbar interaction. Predictions for the proton electromagnetic form
factors G_E and G_M in the timelike region, close to the NNbar threshold, and
for spin-dependent observables are presented. The steep rise of the effective
form factor for energies close to the ppbar threshold is explained solely in
terms of the ppbar interaction. The corresponding experimental information is
quantitatively described by our calculation.Comment: 14 pages, 11 figure
Integral-method analysis for a hypersonic viscous shock layer with mass injection
Integral method analysis for hypersonic viscous shock layer with mass injectio
Multipole Gravitational Lensing and High-order Perturbations on the Quadrupole Lens
An arbitrary surface mass density of gravitational lens can be decomposed
into multipole components. We simulate the ray-tracing for the multipolar mass
distribution of generalized SIS (Singular Isothermal Sphere) model, based on
the deflection angles which are analytically calculated. The magnification
patterns in the source plane are then derived from inverse shooting technique.
As have been found, the caustics of odd mode lenses are composed of two
overlapping layers for some lens models. When a point source traverses such
kind of overlapping caustics, the image numbers change by \pm 4, rather than
\pm 2. There are two kinds of images for the caustics. One is the critical
curve and the other is the transition locus. It is found that the image number
of the fold is exactly the average value of image numbers on two sides of the
fold, while the image number of the cusp is equal to the smaller one. We also
focus on the magnification patterns of the quadrupole (m = 2) lenses under the
perturbations of m = 3, 4 and 5 mode components, and found that one, two, and
three butterfly or swallowtail singularities can be produced respectively. With
the increasing intensity of the high-order perturbations, the singularities
grow up to bring sixfold image regions. If these perturbations are large enough
to let two or three of the butterflies or swallowtails contact, eightfold or
tenfold image regions can be produced as well. The possible astronomical
applications are discussed.Comment: 24 pages, 6 figure
Efimov Physics in 6Li Atoms
A new narrow 3-atom loss resonance associated with an Efimov trimer crossing
the 3-atom threshold has recently been discovered in a many-body system of
ultracold 6Li atoms in the three lowest hyperfine spin states at a magnetic
field near 895 G. O'Hara and coworkers have used measurements of the 3-body
recombination rate in this region to determine the complex 3-body parameter
associated with Efimov physics. Using this parameter as the input, we calculate
the universal predictions for the spectrum of Efimov states and for the 3-body
recombination rate in the universal region above 600 G where all three
scattering lengths are large. We predict an atom-dimer loss resonance at (672
+/- 2) G associated with an Efimov trimer disappearing through an atom-dimer
threshold. We also predict an interference minimum in the 3-body recombination
rate at (759 +/- 1) G where the 3-spin mixture may be sufficiently stable to
allow experimental study of the many-body system.Comment: 27 pages, 9 figures, REVTeX4, published versio
Three-body Recombination of Lithium-6 Atoms with Large Negative Scattering Lengths
The 3-body recombination rate at threshold for distinguishable atoms with
large negative pair scattering lengths is calculated in the zero-range
approximation. The only parameters in this limit are the 3 scattering lengths
and the Efimov parameter, which can be complex valued. We provide semi-analytic
expressions for the cases of 2 or 3 equal scattering lengths and we obtain
numerical results for the general case of 3 different scattering lengths. Our
general result is applied to the three lowest hyperfine states of Lithium-6
atoms. Comparisons with recent experiments provide indications of loss features
associated with Efimov trimers near the 3-atom threshold.Comment: 4 pages, 4 figures, agrees with published versio
Structures of ultrathin copper nanotubes
We have performed atomistic simulations for helical multi-shell (HMS) Cu
nanowires and nanotubes. Our investigation on HMS Cu nanowires and nanotubes
has revealed some physical properties that were not dealt in previous works
that considered metal nanowires. As the diameter of HMS nanowires increased,
their cohesive energy per atom and optimum lattice constant decreased. As the
diameter of HMS nanotubes increases, their cohesive energy per atom decreased
but optimum lattice constant increased. Shell-shell or core-shell interactions
mainly affected on the lattice constant and the diameter of HMS nanowires or
nanotubes. This study showed that HMS nanotubes for materials of fcc metal
crystals can be maintained when forces exerted on atoms of inner shell of the
HMS nanotubes are zero or act on the direction of the outside.Comment: 16 pages, 1 table, 5 figure
Extracting CP violation and strong phase in D decays by using quantum correlations in psi(3770)-> D0\bar{D}0 -> (V1V2)(V3V4) and psi(3770)->D0\bar{D}0 -> (V1V2)(K pi)
The charm quark offers interesting opportunities to cross-check the mechanism
of CP violation precisely tested in the strange and beauty sectors. In this
paper, we exploit the angular and quantum correlations in the D\bar{D} pairs
produced through the decay of the psi(3770) resonance in a charm factory to
investigate CP-violation in two different ways. We build CP-violating
observables in psi(3770) -> D\bar{D} -> (V_1V_2)(V_3 V_4) to isolate specific
New Physics effects in the charm sector. We also consider the case of psi(3770)
-> D\bar{D} -> (V_1V_2)(K\pi) decays, which provide a new way to measure the
strong phase difference delta between Cabibbo-favored and doubly-Cabibbo
suppressed D decays required in the determination of the CKM angle gamma.
Neglecting the systematics, we give a first rough estimate of the sensitivities
of these measurements at BES-III with an integrated luminosity of 20 fb^-1 at
psi(3770) peak and at a future Super tau-charm factory with a luminosity of
10^35 cm^-2.s^-1.Comment: 13 pages
Conformal Invariance of Black Hole Temperature
It is shown that the surface gravity and temperature of a stationary black
hole are invariant under conformal transformations of the metric that are the
identity at infinity. More precisely, we find a conformal invariant definition
of the surface gravity of a conformal Killing horizon that agrees with the
usual definition(s) for a true Killing horizon and is proportional to the
temperature as defined by Hawking radiation. This result is reconciled with the
intimate relation between the trace anomaly and the Hawking effect, despite the
{\it non}invariance of the trace anomaly under conformal transformations.Comment: 8 pages, plain LaTeX, NSF-ITP-93-9
Rotational quantum friction in superfluids: Radiation from object rotating in superfluid vacuum
We discuss the friction experienced by the body rotating in superfluid liquid
at T=0. The effect is analogous to the amplification of electromagnetic
radiation and spontaneous emission by the body or black hole rotating in
quantum vacuum, first discussed by Zel'dovich and Starobinsky. The friction is
caused by the interaction of the part of the liquid, which is rigidly connected
with the rotating body and thus represents the comoving detector, with the
"Minkowski" vacuum outside the body. The emission process is the quantum
tunneling of quasiparticles from the detector to the ergoregion, where the
energy of quasiparticles is negative in the rotating frame. This quantum
rotational friction caused by the emission of quasiparticles is estimated for
phonons and rotons in superfluid 4He and for Bogoliubov fermions in superfluid
3He.Comment: RevTex file, 4 pages, 1 figur
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