Interactions of High Energy Particles with NucleiNational Bureau of Standards, 1975 - 69 pages |
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Page 11
... eik z = II [ 1 — y ; ( b − s ; ) ] ę ik z j = 1 A r ( b , s1 . . . SA ) = 1 — [ 1 - y ; ( b - s , ) ] . j = 1 So , we get again the formulae of section 2 . The previous case dealt with an elementary object scattering from 11 =
... eik z = II [ 1 — y ; ( b − s ; ) ] ę ik z j = 1 A r ( b , s1 . . . SA ) = 1 — [ 1 - y ; ( b - s , ) ] . j = 1 So , we get again the formulae of section 2 . The previous case dealt with an elementary object scattering from 11 =
Page 12
Wiesław Czyż. The previous case dealt with an elementary object scattering from a composite object . We already saw in the ... objects . The formulae given below are interesting also because they may be used to analyze high energy nucleus ...
Wiesław Czyż. The previous case dealt with an elementary object scattering from a composite object . We already saw in the ... objects . The formulae given below are interesting also because they may be used to analyze high energy nucleus ...
Page 14
... objects be R. and Rь . The calculations of ref . [ 12 ] show that the smaller is R , the nearer we are to the additivity of ( b ) -nucleon phase shifts . But that means that this additivity improves with increase of the binding of ( b ) ...
... objects be R. and Rь . The calculations of ref . [ 12 ] show that the smaller is R , the nearer we are to the additivity of ( b ) -nucleon phase shifts . But that means that this additivity improves with increase of the binding of ( b ) ...
Page 15
... objects ( e.g. , their transverse density distributions ) . If these geometric characteristics do not depend on energy , one gets the total cross section ( from the optical theorem ) which is energy independent . So , it seems to be ...
... objects ( e.g. , their transverse density distributions ) . If these geometric characteristics do not depend on energy , one gets the total cross section ( from the optical theorem ) which is energy independent . So , it seems to be ...
Page 28
... objects . The model of diffractive processes described below is based on : M. L. Good and W. D. Walker ( 1960 ) [ 23 ] . The article which discusses some very early papers on the subject is : E. L. Feinberg and I. Pomerančuk ( 1956 ) ...
... objects . The model of diffractive processes described below is based on : M. L. Good and W. D. Walker ( 1960 ) [ 23 ] . The article which discusses some very early papers on the subject is : E. L. Feinberg and I. Pomerančuk ( 1956 ) ...
Common terms and phrases
absorption additivity analysis approximately assume attenuation beam coherent collision complete components compute consider contribution corrections Coulomb Coulomb interactions coupling cross section db exp db exp i▲·b depend describe deuteron diffractive production processes discussed effects elastic scattering elastic scattering amplitude equation example excited existence experimental experiments expression fact factor field final formula forward given gives Glauber ground hadrons Hence high energy limit important incident particle inelastic initial Institute interactions introduce magnetic mass measurement momentum transfer multiple scattering Note nuclear nuclear targets nuclei nucleon numbers objects obtained parameters phase shifts photon photoproduction physical position possible problem profiles regeneration shadowing single Standards step strong structure technical vector meson wave function weak