27,749 research outputs found
Adaptive reflection and focusing of Bose-Einstein condensates
We report adjustable magnetic `bouncing' and focusing of a dilute Rb
Bose gas. Both the condensate production and manipulation are realised using a
particularly straight-forward apparatus. The bouncing region is comprised of
approximately concentric ellipsoidal magnetic equipotentials with a centre that
can be adjusted vertically. We extend, and discuss the limitations of, simple
Thomas-Fermi and Monte-Carlo theoretical models for the bouncing, which at
present find close agreement with the condensate's evolution. Very strong
focusing has been inferred and the observation of atomic matter-wave
diffraction should be possible. Prospects look bright for applications in
matter-wave atom-optics, due to the very smooth nature of the mirror
A computer program for a line-by-line calculation of spectra from diatomic molecules and atoms assuming a Voight line profile
Computer program predicts the spectra resulting from electronic transitions of diatomic molecules and atoms in local thermodynamic equilibrium. The program produces a spectrum by accounting for the contribution of each rotational and atomic line considered
Transport Coefficients of Gluon Plasma
Transport coefficients of gluon plasma are calculated for a SU(3) pure gauge
model by lattice QCD simulations on and
lattices. Simulations are carried out at a slightly above the deconfinement
transition temperature , where a new state of matter is currently being
pursued in RHIC experiments. Our results show that the ratio of the shear
viscosity to the entropy is less than one and the bulk viscosity is consistent
with zero in the region, .Comment: 10 pages, Late
Degree of randomness: numerical experiments for astrophysical signals
Astrophysical and cosmological signals such as the cosmic microwave
background radiation, as observed, typically contain contributions of different
components, and their statistical properties can be used to distinguish one
from the other. A method developed originally by Kolmogorov is involved for the
study of astrophysical signals of randomness of various degrees. Numerical
performed experiments based on the universality of Kolmogorov distribution and
using a single scaling of the ratio of stochastic to regular components, reveal
basic features in the behavior of generated signals also in terms of a critical
value for that ratio, thus enable the application of this technique for various
observational datasetsComment: 6 pages, 9 figures; Europhys.Letters; to match the published versio
Radiative and Collisional Energy Loss, and Photon-Tagged Jets at RHIC
The suppression of single jets at high transverse momenta in a quark-gluon
plasma is studied at RHIC energies, and the additional information provided by
a photon tag is included. The energy loss of hard jets traversing through the
medium is evaluated in the AMY formalism, by consistently taking into account
the contributions from radiative events and from elastic collisions at leading
order in the coupling. The strongly-interacting medium in these collisions is
modelled with (3+1)-dimensional ideal relativistic hydrodynamics. Putting these
ingredients together with a complete set of photon-production processes, we
present a calculation of the nuclear modification of single jets and
photon-tagged jets at RHIC.Comment: 4 pages, 4 figures, contributed to the 3rd International Conference
on Hard and Electro-Magnetic Probes of High-Energy Nuclear Collisions (Hard
Probes 2008), typos corrected, published versio
A large magnetic storage ring for Bose-Einstein condensates
Cold atomic clouds and Bose-Einstein condensates have been stored in a 10cm
diameter vertically-oriented magnetic ring. An azimuthal magnetic field enables
low-loss propagation of atomic clouds over a total distance of 2m, with a
heating rate of less than 50nK/s. The vertical geometry was used to split an
atomic cloud into two counter-rotating clouds which were recombined after one
revolution. The system will be ideal for studying condensate collisions and
ultimately Sagnac interferometry.Comment: 4 pages, 5 figure
Measurement of temperature profiles in hot gases and flames
Computer program was written for calculation of molecular radiative transfer from hot gases. Shape of temperature profile was approximated in terms of simple geometric forms so profile could be characterized in terms of few parameters. Parameters were adjusted in calculations using appropriate radiative-transfer expression until best fit was obtained with observed spectra
Normalizations with exponentially small remainders for nonautonomous analytic periodic vector fields
In this paper we deal with analytic nonautonomous vector fields with a
periodic time-dependancy, that we study near an equilibrium point. In a first
part, we assume that the linearized system is split in two invariant subspaces
E0 and E1. Under light diophantine conditions on the eigenvalues of the linear
part, we prove that there is a polynomial change of coordinates in E1 allowing
to eliminate up to a finite polynomial order all terms depending only on the
coordinate u0 of E0 in the E1 component of the vector field. We moreover show
that, optimizing the choice of the degree of the polynomial change of
coordinates, we get an exponentially small remainder. In the second part, we
prove a normal form theorem with exponentially small remainder. Similar
theorems have been proved before in the autonomous case : this paper
generalizes those results to the nonautonomous periodic case
QCD and QED dynamics of the EMC effect
Applying exact QCD sum rules for the baryon charge and energy-momentum we
demonstrate that if nucleons are the only degrees of freedom of nuclear wave
function, the structure function of a nucleus would be the additive sum of the
nucleon distributions at the same Bjorken x = AQ^2/2(p_Aq)< 0.5 up to very
small Fermi motion corrections if x>0.05. Thus the difference of the EMC ratio
from one reveals the presence of non-nucleonic degrees of freedom in nuclei.
Using exact QCD sum rules we show that the ratio R_A(x_p,Q^2) used in
experimental studies, where x_p = Q^2/2q_0 m_p deviates from one even if a
nucleus consists of nucleons with small momenta only. Use of the Bjorken x
leads to additional decrease of R_A(x,Q^2) as compared to the x_p plots.
Coherent contribution of equivalent photons into photon component of parton
wave function of a nucleus unambiguously follows from Lorentz transformation of
the rest frame nucleus Coulomb field. For A~200 photons carry ~0.0065 fraction
of the light momentum of nucleus almost compensates the difference between data
analysis in terms of Bjorken x and x_p. Different role of higher twist effects
for Q^2 probed at electron and muon beams is emphasized. Direct observations of
large and predominantly nucleonic short-range correlations in nuclei pose a
serious challenge for most of the models of the EMC effect for x>0.6. The data
are consistent with a scenario in which the hadronic EMC effect reflects
fluctuations of inter nucleon interaction due to fluctuations of color
distribution in the interacting nucleons. The dynamic realization of this
scenario is the model in which the 3q (3qg) configurations with x > 0.5 parton
have a weaker interaction with nearby nucleons, leading to suppression of such
configurations giving a right magnitude of the EMC effect. The directions for
the future studies and challenging questions are outlined.Comment: The sign in the relation of x_Bj and x_p is corrected and the
following discussion is adjusted accordingly. Discussion of the higher twist
effects is adde
- …