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On the scalar pi K form factor beyond the elastic region

von Detten, L., Noël, F., Hanhart, C., Hoferichter, Martin, Kubis, B.

2021Bern Open Repository and Information System (University of Bern)20 citationsDOIOpen Access PDF

Abstract

Pion-kaon ($\pi K$) pairs occur frequently as final states in heavy-particle decays. A consistent treatment of $\pi K$ scattering and production amplitudes over a wide energy range is therefore mandatory for multiple applications: in Standard Model tests; to describe crossed channels in the quest for exotic hadronic states; and for an improved spectroscopy of excited kaon resonances. In the elastic region, the phase shifts of $\pi K$ scattering in a given partial wave are related to the phases of the respective $\pi K$ form factors by Watson's theorem. Going beyond that, we here construct a representation of the scalar $\pi K$ form factor that includes inelastic effects via resonance exchange, while fulfilling all constraints from $\pi K$ scattering and maintaining the correct analytic structure. As a first application, we consider the decay ${\tau\to K_S\pi\nu_\tau}$, in particular, we study to which extent the $S$-wave $K_0^*(1430)$ and the $P$-wave $K^*(1410)$ resonances can be differentiated and provide an improved estimate of the $CP$ asymmetry produced by a tensor operator. Finally, we extract the pole parameters of the $K_0^*(1430)$ and $K_0^*(1950)$ resonances via Pad\'e approximants, $\sqrt{s_{K_0^*(1430)}}=[1408(48)-i\, 180(48)]$ MeV and $\sqrt{s_{K_0^*(1950)}}=[1863(12)-i\,136(20)]$ MeV, as well as the pole residues. A generalization of the method also allows us to formally define a branching fraction for ${\tau\to K_0^*(1430) \nu_\tau}$ in terms of the corresponding residue, leading to the upper limit ${\text{BR}(\tau\to K_0^*(1430) \nu_\tau)<1.6 \times 10^{-4}}$.

Topics & Concepts

PhysicsHadronPionScalar (mathematics)Form factor (electronics)PiParticle physicsAmplitudeResonance (particle physics)ScatteringElastic scatteringPartial wave analysisMathematical physicsQuantum mechanicsGeometryBiochemistryChemistryMathematicsQuantum Chromodynamics and Particle InteractionsParticle physics theoretical and experimental studiesHigh-Energy Particle Collisions Research