Quark Reggeization in QCD from the Wilson line formalism

Abstract

We derive quark Reggeization in QCD at leading logarithmic accuracy within the eikonal Wilson-line (shockwave) approach. An interpolating operator for the Reggeized quark is identified in terms of semi-infinite Wilson lines, and its nonlinear rapidity renormalization-group evolution is derived using the background-field method. In the dilute limit, after projecting onto operators of definite signature, the positive-signature channel reproduces the characteristic power-law scaling dictated by the one-loop quark Regge trajectory, whereas the negative-signature channel exhibits mixing between Reggeized quark and gluon exchanges. In the large-Nc limit, this mixing disappears, and Regge-pole behaviour emerges without the need for signature projection, recovering the expected degeneracy by signature. This paves the way to a systematic all-order analysis of high-energy QCD amplitudes with t-channel quark quantum-number exchange in terms of eikonal Wilson lines.