Chiral symmetry, the angular content of the vector current in QED and QCD, and the holographic description of hadrons

Abstract

We perform a general chiral symmetry and unitarity based analysis of a local process of the fermion-antifermion creation from the vacuum by a high-energy photon as well as an explicit partial wave analysis of the vector current in QED and QCD. It turns out that such a local process proceeds necessarily via a certain superposition of the S- and D-wave contributions. These constraints from chiral symmetry and unitarity are confronted then with the well-known theoretical and experimental results on e+e-γ e+e-, e+e-γ μ+μ-, and e+e-γ qq in the ultrarelativistic limit. It is shown that these well-known results are consistent with the S+D-wave structure of the vertex and are inconsistent with the pure S-wave interpretation of the vertex. Then a free quark loop in the 1-- channel, representing the leading term in the Operator Product Expansion, contains both S-wave and D-wave contributions. This fact rules out the possibility that there is only one radial trajectory for the -mesons with the fixed S-wave content. It also implies that all holographic models that assume a pure S-wave content of the -meson have to fail to satisfy the matching conditions at the ultraviolet border z=0.