D-wave effects in diffractive electroproduction of heavy quarkonia from the photon-like V→ Q Q transition

Abstract

We analyze the validity of a commonly used identification between structures of the virtual photon γ* Q Q and vector meson V Q Q transitions. In the existing studies of S-wave vector-meson photoproduction in the literature, such an identification is typically performed in the light-front (LF) frame while the radial component of the meson wave function is rather postulated than computed from the first principles. The massive photon-like V Q Q vertex, besides the S-wave component, also contains an extra D-wave admixture in the Q Q rest frame. However, the relative weight of these contributions cannot be justified by any reasonable nonrelativistic Q Q potential model. In this work, we investigate the relative role of the D-wave contribution starting from the photon-like quarkonium V Q Q transition in both frames: in the Q Q rest frame (with subsequent Melosh spin transform to the LF frame) and in the LF frame (without Melosh transform). We show that the photon-like transition imposed in the Q Q rest frame leads to significant discrepancies with the experimental data. In the second case we find that the corresponding total J/(1S) photoproduction cross sections are very close to those obtained with the "S-wave only" V Q Q transition, both leading to a good description of the data. However, we find that the "S-wave only" transition leads to a better description of photoproduction data for excited heavy quarkonium states, which represent a more effective tool for study of D-wave effects. Consequently, the predictions for production of excited states based on the photon-like structure of V Q Q transition should be treated with a great care due to a much stronger sensitivity of the D-wave contribution to the nodal structure of quarkonium wave functions.