Symmetry-preserving calculation of pion light-front wave functions
Abstract
Poincar\'e-covariant Bethe-Salpeter wave functions are used to calculate light-front wave functions (LFWFs) of the pion, π, and an analogue state, πs s. The current masses of the degenerate valence constituents in the πs s are around 25-times larger than those of the pion's valence constituents. Both valence spin-antialigned ( L=0) and valence spin-aligned ( L=1) components are obtained and combined to produce the complete LFWF for each system. Comparing predictions delivered by two distinct Bethe-Salpeter kernels, the impact of nonperturbative dynamical effects contained in the more sophisticated (bRL) kernel are seen to be significant; and contrasts between π, πs s results reveal the interplay between emergent hadron mass and mass effects owing to Higgs-boson couplings. Amongst the results, one finds that for π, πs s, the LFWFs can be approximated by a separable form, with that representation being pointwise reliable in the bRL cases. Moreover, the L=1 component is important; so a LFWF obtained after omission of this piece is typically a poor representation of the system. These features are naturally expressed in π, πs s transverse momentum dependent parton distribution functions (TMDs). In this connection, it is found that a Gaussian Ansatz can only provide a rough guide to TMD pointwise behaviour: magnitude deviations between Ansatz and prediction exceed a factor of two on k2 0.55\,GeV2. One should therefore be cautious in interpreting conclusions drawn from phenomenological analyses based upon Gaussian Ans\"atze.
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