Electron-Nucleus Collisions at THERA
Abstract
The nuclear option at THERA provides an ideal and unique opportunity to investigate the black body limit (BBL) of high energy Deep Inelastic Scattering of highly virtual photons off heavy nuclear targets and thereby probe QCD in a new regime. At high enough energies, whichever hadronic configuration the photon fluctuates into, the interaction at a given impact parameter with the heavy nuclear target will eventually reach its geometrical limit corresponding to the scattering from a black disk. An attractive feature of the BBL regime for a large nucleus is that the interaction is strong although the coupling constant is small. Predictions for longitudinal and transverse distributions of the leading hadrons in inclusive and diffractive channels and exclusive vector meson production are found to be strikingly different in BBL and the leading twist approximation. In particular, the multiplicity of leading hadrons in the current fragmentation region is strongly suppressed, while the cross section of diffractive vector meson production by longitudinally polarized photons is 1/Q2. The x and Q2 ranges where BBL maybe reached are calculated for the interaction of color triplet and color octet dipoles at central impact parameters. We conclude that for heavy nuclei THERA would reach deep into BBL for a wide range of Q2. The connection between hard diffraction and leading twist nuclear shadowing is analysed. It is demonstrated that the current leading twist analyses of the HERA diffractive data lead to similar and very large leading twist shadowing for gluons. Several processes sensitive to the amount of nuclear shadowing for gluons are discussed.
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