Triple-Pomeron Matrix Model for Dispersive Corrections to
  Nucleon-Nucleus Total Cross Section

B. Blaettel; B. Kopeliovich; B.K. Jennings; C.-I. Tan; D.R. Harrington; D.R. Harrington; D.R. Harrington; D.R. Harrington; David R. Harrington; G.V. Bachmann; H. Feshbach; J. Huefner; K. Goulianos; K. Goulianos; K.S. Koelbig; L. Frankfurt; L. Frankfurt; L.V. Hove; M. Ross; M.L. Good; P.V.R. Murthy; R.L. Cool; S.D. Drell; V.N. Gribov

research

Triple-Pomeron Matrix Model for Dispersive Corrections to Nucleon-Nucleus Total Cross Section

Authors: B. Blaettel
B. Kopeliovich
B.K. Jennings
C.-I. Tan
D.R. Harrington
D.R. Harrington
D.R. Harrington
D.R. Harrington
David R. Harrington
G.V. Bachmann
H. Feshbach
J. Huefner
K. Goulianos
K. Goulianos
K.S. Koelbig
L. Frankfurt
L. Frankfurt
L.V. Hove
M. Ross
M.L. Good
P.V.R. Murthy
R.L. Cool
S.D. Drell
V.N. Gribov
Publication date: 14 June 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Dispersive corrections to the total cross section for high-energy scattering from a heavy nucleus are calculated using a matrix model, based on the triple-Pomeron behavior of diffractive scattering from a single nucleon, for the cross section operator connecting different states of the projectile nucleon . Energy-dependent effects due to the decrease in longitudinal momentum transfers and the opening of more channels with increasing energy are included. The three leading terms in an expansion in the number of inelastic transitions are evaluated and compared to exact results for the model in the uniform nuclear density approximation for the the scattering of nucleons from Pb^{208} for laboratory momenta ranging from 50 to 200 GeV/c.Comment: 16 pages, 2 figures, RevTex

Similar works

Full text

Available Versions

Crossref

Last time updated on 11/12/2019