Relativistic Coulomb Sum Rules for $(e,e^\prime)$

A.L. Fetter; B.D. Serot; C.J. Horowitz; C.R. Chinn; C.R. Chinn; C.R. Chinn; D. S. Koltun; G. Do Dang; G. Do Dang; J.P. Chen; K.J. Barnes; K.W. McVoy; L.N. Hand; R. Schiavilla; S.J. Wallace; T. C. Ferrée; T. Matsui; T.C. Ferrée; Z. E. Meziani

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Relativistic Coulomb Sum Rules for $(e,e^\prime)$

Authors: A.L. Fetter
B.D. Serot
C.J. Horowitz
C.R. Chinn
C.R. Chinn
C.R. Chinn
D. S. Koltun
G. Do Dang
G. Do Dang
J.P. Chen
K.J. Barnes
K.W. McVoy
L.N. Hand
R. Schiavilla
S.J. Wallace
T. C. Ferrée
T. Matsui
T.C. Ferrée
Z. E. Meziani
Publication date: 14 January 1994
Publisher: 'American Physical Society (APS)'
Doi

Abstract

A Coulomb sum rule is derived for the response of nuclei to

(e,e^\prime)

scattering with large three-momentum transfers. Unlike the nonrelativistic formulation, the relativistic Coulomb sum is restricted to spacelike four-momenta for the most direct connection with experiments; an immediate consequence is that excitations involving antinucleons, e.g.,

N{\bar N}

pair production, are approximately eliminated from the sum rule. Relativistic recoil and Fermi motion of target nucleons are correctly incorporated. The sum rule decomposes into one- and two-body parts, with correlation information in the second. The one-body part requires information on the nucleon momentum distribution function, which is incorporated by a moment expansion method. The sum rule given through the second moment (RCSR-II) is tested in the Fermi gas model, and is shown to be sufficiently accurate for applications to data.Comment: 32 pages (LaTeX), 4 postscript figures available from the author