16,950 research outputs found
Hard core attraction in hadron scattering and the family of the Ds meson molecule
We study the discovered Ds(2317) at BABAR, CLEO and BELLE, and find that it
belongs to a class of strange multiquarks, which is equivalent to the class of
kaonic molecules bound by hard core attraction. In this class of hadrons a kaon
is trapped by a s-wave meson or baryon. To describe this class of multiquarks
we apply the Resonating Group Method, and extract the hard core
kaon-meson(baryon)interactions. We derive a criterion to classify the
attractive channels. We find that the mesons f0(980), Ds(2457), Bs scalar and
axial, and also the baryons with the quantum numbers of Lambda, Xi_c, Xi_b and
also Omega_cc, Omega_cb and Omega_bb belong to the new hadronic class of the
Ds(2317).Comment: 5 pages, 1 figure, 2 tables, contribution to the X International
Conference on Hadron Spectroscopy, HADRON 2003, August 31 - September 6,
2003, Aschaffenburg, German
The Theta+ (1540) as an overlap of a pion, a kaon and a nucleon
We study the very recently discovered (1540) at SPring-8, at ITEP
and at CLAS-Thomas Jefferson Lab. We apply the same RGM techniques that already
explained with success the repulsive hard core of nucleon-nucleon, kaon-nucleon
exotic scattering, and the attractive hard core present in pion-nucleon and
pion-pion non-exotic scattering. We find that the K-N repulsion excludes the
Theta+ as a K-N s-wave pentaquark. We explore the Theta+ as heptaquark,
equivalent to a N+pi+K borromean boundstate, with positive parity and total
isospin I=0. We find that the kaon-nucleon repulsion is cancelled by the
attraction existing both in the pion-nucleon and pion-kaon channels. Although
we are not yet able to bind the total three body system, we find that the
Theta+ may still be a heptaquark state.Comment: 5 pages, 3 figures, 1 table, contribution to the X International
Conference on Hadron Spectroscopy, HADRON 2003, August 31 - September 6,
2003, Aschaffenburg, German
Hawking radiation for non asymptotically flat dilatonic black holes using gravitational anomaly
The -dimensional scalar field action may be reduced, in the background
geometry of a black hole, to a 2-dimensional effective action. In the near
horizon region, it appears a gravitational anomaly: the energy-momentum tensor
of the scalar field is not conserved anymore. This anomaly is removed by
introducing a term related to the Hawking temperature of the black hole. Even
if the temperature term introduced is not covariant, a gauge transformation may
restore the covariance. We apply this method to compute the temperature of the
black hole of the dilatonic non asymptotically flat black holes. We compare the
results with those obtained through other methods.Comment: Latex file, 22 pages. Some discussions enlarged. New references.
Accepted for publication in the European Physical Journal
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