Quark fragmentation in the θ-vacuum

Abstract

The vacuum of Quantum Chromodynamics is a superposition of degenerate states with different topological numbers that are connected by tunneling (the θ-vacuum). The tunneling events are due to topologically non-trivial configurations of gauge fields (e.g. the instantons) that induce local -odd domains in Minkowski space-time. We study the quark fragmentation in this topologically non-trivial QCD background. We find that even though QCD globally conserves and symmetries, two new kinds of -odd fragmentation functions emerge. They generate interesting dihadron correlations: one is the azimuthal angle correlation (φ1 + φ2) usually referred to as the Collins effect, and the other is the -odd correlation (φ1 + φ2) that vanishes in the cross section summed over many events, but survives on the event-by-event basis. Using the chiral quark model we estimate the magnitude of these new fragmentation functions. We study their experimental manifestations in dihadron production in e+e- collisions, and comment on the applicability of our approach in deep-inelastic scattering, proton-proton and heavy ion collisions.