The a1(1420) in a Unitary Coupled-Channel Three-Body Approach

Abstract

An enhancement in the three-pion energy at around s≈ 1.42~GeV with a1 quantum numbers was observed at the COMPASS experiment. This was later attributed to the triangle singularity mechanism involving an on-shell K*(892), K and K intermediate states. The alignment of the decay K with the spectator K produces an f0(980), resulting in a kinematic enhancement, which is classically explained by the Landau equations. However, this one-loop process forms only part of a non-diagonal transition in a much larger coupled-channel framework. This study demonstrates the feasibility of embedding one-loop triangle-singularity calculations into a unitary three-body amplitude allowing one to consistently incorporate final-state interactions and their potentially substantial effect. For this, up to P-wave isobars and all sub-channel isospins are combined in a nine-channel production amplitude that is fitted to COMPASS lineshapes at different momentum transfers. The fitted amplitude reproduces the narrow enhancement in the (πf0)P channel near s≈1.42 GeV. This implies that the triangle singularity mechanism sufficiently explains the observed enhancement, and an additional genuine a1(1420) pole is not required. Incidentally, the parameters of the ground state axial vector resonance (the a1(1260)) are also extracted from that data.