QCD Compositeness as Revealed in Exclusive Vector Boson Reactions through Double-Photon Annihilation: e+ e- γ γ γ V0 and e+ e- γ γ V0 V0

Abstract

We study the exclusive double-photon annihilation processes, e+ e- γ γ γ V0 and e+ e- γ γ V0a V0b, where the V0i is a neutral vector meson produced in the forward kinematical region: s -t and -t QCD2. We show how the differential cross sections dσdt, as predicted by QCD, have additional falloff in the momentum transfer squared t due to the QCD compositeness of the hadrons, consistent with the leading-twist fixed-θ CM scaling laws. However, even though they are exclusive channels and not associated with the conventional electron-positron annihilation process e+ e- γ q q, these total cross sections σ(e+ e- γ V0) and σ(e+ e- V0a V0b), integrated over the dominant forward- and backward-θ CM angular domains, scale as 1/s, and thus contribute to the leading-twist scaling behavior of the ratio Re+ e-. We generalize these results to exclusive double-electroweak vector-boson annihilation processes accompanied by the forward production of hadrons, such as e+ e- Z0 V0 and e+ e- W-+. These results can also be applied to the exclusive production of exotic hadrons such as tetraquarks, where the cross-section scaling behavior can reveal their multiquark nature.