Abstract
Using the dipole picture for electron-nucleus deep inelastic scattering at small Bjorken x, we study the effects of gluon saturation in the nuclear target on the cross-section for SIDIS (single inclusive hadron, or jet, production). We argue that the sensitivity of this process to gluon saturation can be enhanced by tagging on a hadron (or jet) which carries a large fraction z ≃ 1 of the longitudinal momentum of the virtual photon. This opens the possibility to study gluon saturation in relatively hard processes, where the virtuality Q2 is (much) larger than the target saturation momentum {Q}_s^2 , but such that z(1 − z)Q2 ≲ {Q}_s^2 . Working in the limit z(1 − z)Q2 ≪ {Q}_s^2 , we predict new phenomena which would signal saturation in the SIDIS cross-section. For sufficiently low transverse momenta k⊥ ≪ Qs of the produced particle, the dominant contribution comes from elastic scattering in the black disk limit, which exposes the unintegrated quark distribution in the virtual photon. For larger momenta k⊥ ≳ Qs, inelastic collisions take the leading role. They explore gluon saturation via multiple scattering, leading to a Gaussian distribution in k⊥ centred around Qs. When z(1 − z)Q2 ≪ Q2, this results in a Cronin peak in the nuclear modification factor (the RpA ratio) at moderate values of x. With decreasing x, this peak is washed out by the high-energy evolution and replaced by nuclear suppression (RpA< 1) up to large momenta k⊥ ≫ Qs. Still for z(1 − z)Q2 ≪ {Q}_s^2 , we also compute SIDIS cross-sections integrated over k⊥. We find that both elastic and inelastic scattering are controlled by the black disk limit, so they yield similar contributions, of zeroth order in the QCD coupling.
Highlights
One of the main objectives of the future experimental program at the Electron-Ion Collider (EIC) [1, 2] is an in-depth study of the regime of high parton densities in the wavefunction of a large nucleus accelerated to ultrarelativistic energies
Using the dipole picture for electron-nucleus deep inelastic scattering at small Bjorken x, we study the effects of gluon saturation in the nuclear target on the cross-section for SIDIS
We argue that the sensitivity of this process to gluon saturation can be enhanced by tagging on a hadron which carries a large fraction z 1 of the longitudinal momentum of the virtual photon
Summary
One of the main objectives of the future experimental program at the Electron-Ion Collider (EIC) [1, 2] is an in-depth study of the regime of high parton densities in the wavefunction of a large nucleus accelerated to ultrarelativistic energies. We make the observation that saturation effects in relatively hard eA collisions with Q2 Q2s could be observed at the EIC in an even simpler process, the semi-inclusive production of a single hadron (or jet), a.k.a. SIDIS, provided the measured particle/jet is very forward — meaning that it carries a large fraction z 1 of the longitudinal momentum of the virtual photon. The respective contributions come from integrating k⊥-dependent physics which is quite different in the two cases: the γT∗ -wavefunction in the case of the elastic scattering and, respectively, the k⊥-broadening of the measured quark for the inelastic one We find it interesting to study the weak scattering regime at large effective virtuality Q2 Q2s, where saturation is still visible, albeit rather indirectly, via the phenomenon of geometric scaling [57,58,59]. We have relegated some of the calculations to five appendices, out of which one is devoted to a brief review of the collinearly-improved BK equation
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