13,339 research outputs found
Quenching of Cross Sections in Nucleon Transfer Reactions
Cross sections for proton knockout observed in (e,e'p) reactions are
apparently quenched by a factor of ~0.5, an effect attributed to short-range
correlations between nucleons. Here we demonstrate that such quenching is not
restricted to proton knockout, but a more general phenomenon associated with
any nucleon transfer. Measurements of absolute cross sections on a number of
targets between 16O and 208Pb were analyzed in a consistent way, with the cross
sections reduced to spectroscopic factors through the distorted-wave Born
approximation with global optical potentials. Across the 124 cases analyzed
here, induced by various proton- and neutron-transfer reactions and with
angular momentum transfer l=0-7, the results are consistent with a quenching
factor of 0.55. This is an apparently uniform quenching of single-particle
motion in the nuclear medium. The effect is seen not only in (d,p) reactions
but also in reactions with A=3 and 4 projectiles, when realistic wave functions
are used for the projectiles.Comment: 5 pages, 3 figures, accepted to Physical Review Letter
High-j single-particle neutron states outside the N=82 core
The behaviour of the i13/2 and h9/2 single-neutron strength was studied with
the (4He,3He) reaction on 138Ba, 140Ce, 142Nd and 144Sm targets at a beam
energy of 51 MeV. The separation between the single-neutron states i13/2 and
h9/2 was measured in N =83 nuclei with changing proton number. To this end
spectroscopic factors for states populated in high-l transfer were extracted
from the data. Some mixing of l=5 and 6 strength was observed with states that
are formed by coupling the f7/2 state to the 2+ and 3- vibrational states and
the mixing matrix elements were found to be remarkably constant. The centroids
of the strength indicate a systematic change in the energies of the i13/2 and
h9/2 single-neutron states with increasing proton number that is in
quantitative agreement with the effects expected from the tensor interaction.Comment: 12 pages of text, 3 diagram
Random field spin models beyond one loop: a mechanism for decreasing the lower critical dimension
The functional RG for the random field and random anisotropy O(N)
sigma-models is studied to two loop. The ferromagnetic/disordered (F/D)
transition fixed point is found to next order in d=4+epsilon for N > N_c
(N_c=2.8347408 for random field, N_c=9.44121 for random anisotropy). For N <
N_c the lower critical dimension plunges below d=4: we find two fixed points,
one describing the quasi-ordered phase, the other is novel and describes the
F/D transition. The lower critical dimension can be obtained in an
(N_c-N)-expansion. The theory is also analyzed at large N and a glassy regime
is found.Comment: 4 pages, 5 figure
A New Approach to Time Domain Classification of Broadband Noise in Gravitational Wave Data
Broadband noise in gravitational wave (GW) detectors, also known as triggers,
can often be a deterrant to the efficiency with which astrophysical search
pipelines detect sources. It is important to understand their instrumental or
environmental origin so that they could be eliminated or accounted for in the
data. Since the number of triggers is large, data mining approaches such as
clustering and classification are useful tools for this task. Classification of
triggers based on a handful of discrete properties has been done in the past. A
rich information content is available in the waveform or 'shape' of the
triggers that has had a rather restricted exploration so far. This paper
presents a new way to classify triggers deriving information from both trigger
waveforms as well as their discrete physical properties using a sequential
combination of the Longest Common Sub-Sequence (LCSS) and LCSS coupled with
Fast Time Series Evaluation (FTSE) for waveform classification and the
multidimensional hierarchical classification (MHC) analysis for the grouping
based on physical properties. A generalized k-means algorithm is used with the
LCSS (and LCSS+FTSE) for clustering the triggers using a validity measure to
determine the correct number of clusters in absence of any prior knowledge. The
results have been demonstrated by simulations and by application to a segment
of real LIGO data from the sixth science run.Comment: 16 pages, 16 figure
Shell model description of Ge isotopes
A shell model study of the low energy region of the spectra in Ge isotopes
for is presented, analyzing the excitation energies,
quadrupole moments, values and occupation numbers. The theoretical
results have been compared with the available experimental data. The shell
model calculations have been performed employing three different effective
interactions and valence spaces.We have used two effective shell model
interactions, JUN45 and jj44b, for the valence space
without truncation. To include the proton subshell in valence space
we have employed the effective interaction due to Sorlin {\it et al.},
with Ca as a core and a truncation in the number of excited particles.Comment: 10 pages, 10 figures, Proc. of the XXXV Nuclear Physics Symposium,
January 3-6 2012, Cocoyoc, Morelos, Mexico. IOP Journal of Physics:
Conference Series (in press
Distributional Modes for Scalar Field Quantization
We propose a mode-sum formalism for the quantization of the scalar field
based on distributional modes, which are naturally associated with a slight
modification of the standard plane-wave modes. We show that this formalism
leads to the standard Rindler temperature result, and that these modes can be
canonically defined on any Cauchy surface.Comment: 15 pages, RevTe
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