Centauric 1-Jettiness in DIS and Universal Power Corrections

Abstract

We introduce the Centauric 1-jettiness, τ1C, a generalized event shape for Deep Inelastic Scattering (DIS) with adjustable beam and jet reference vectors and thus beam and jet regions. We demonstrate that a specific choice of weights allows this observable to exactly reproduce the geometric boundaries of the Centauro jet algorithm in the Breit frame. Within the framework of Soft-Collinear Effective Theory (SCET), we derive a factorized cross section in the small-τ1C region in terms of known perturbative ingredients. This allows the resummation of large logarithms to N3LL accuracy, which we then match to fixed-order NLO QCD (O(αs2)) predictions from NLOJet++. We establish that the soft measurement reduces to a rescaled hemisphere measurement, placing Centauric 1-jettiness in the same universality class, for the leading non-perturbative corrections, as DIS thrust and jet mass. As a consequence, the leading non-perturbative shift depends on the same universal first-moment-shift parameter Ω1 and scales exactly as 1/R with the jet radius, thanks to the boost invariance of the Centauro algorithm along the photon axis in the Breit frame, a scaling that we test using Pythia simulations. These results open new strategies for determining the strong coupling from DIS event shapes, with R providing a handle to break the degeneracy between αs and the universal non-perturbative shift parameter Ω1.