Effective Color Dipole Approach to Color Transparency in ρ0 Electroproduction

Abstract

We investigate nuclear transparency in exclusive ρ0 electroproduction on 12C and 56Fe nuclei within a multi-channel final-state interaction (FSI) framework that explicitly incorporates the kinematic decay length effect (DLE) arising from the short-lived ρ0π+π- decay. The purely kinematic and nuclear mechanisms prove insufficient to account for the CLAS data: the DLE alone cannot generate the observed Q2-dependent enhancement, and the inclusion of nuclear shadowing further deepens the disagreement, so that a compensating reduction of the in-medium attenuation -- the hallmark of color transparency (CT) -- is required. To incorporate the color dynamics of the initially compact qq configuration, we replace the empirical Quantum Diffusion Model (QDM) ansatz for the initial interaction cross section σh(Q2) of the point-like configuration (PLC) by an effective Color Dipole Model (CDM) boundary condition, evaluated through a normalized dipole-weighted γ*ρ0 transition overlap. Combined with the standard linear QDM transport at an effective in-medium expansion scale Δm2 = 0.3~GeV2, the CDM boundary condition reproduces both the magnitude and the Q2 dependence of the data for both targets. A χ2 analysis quantifies the pronounced separation between the non-CT and CT-based descriptions and thereby supports the onset of color transparency in the ρ0 channel beyond what kinematic decay-length effects can accommodate.

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