Model Independent Measurement of \swave $K^{-}\pi^{+}$ systems using $\Dp\to K\pi\pi$ Decays from Fermilab E791

TL;DR

This paper presents a novel, model-independent partial-wave analysis of the S-wave component in $K o\pi$ systems from $D^+$ decays, revealing phase variations inconsistent with existing scattering data and suggesting complex interactions.

Contribution

It introduces a new approach to analyze three-body decays without relying on a specific model for the S-wave, using amplitude measurements across invariant mass ranges from Fermilab E791 data.

Findings

Observed phase variations differ from existing $K o\pi$ scattering measurements.

Indicates possible interactions with other pions affecting phase behavior.

Production rate shows significant invariant mass dependence above 1.25 GeV/c^2.

Abstract

A model-independent partial-wave analysis of the \swave component of the $K\pi$ system from decays of $D^{+}$ mesons to the three-body $\Km\pip\pip$ final state is described. Data come from the Fermilab E791 experiment. Amplitude measurements are made independently for ranges of $\Km\pip$ invariant mass, and results are obtained below 825 \MeVcc, where previous measurements exist only in two mass bins. This method of parametrizing a three-body decay amplitude represents a new approach to analysing such decays. Though no model is required for the \swave, a parametrization of the relatively well-known reference \pdash and \dwave s, optimized to describe the data used, is required. In this paper, a Breit-Wigner model is adopted to describe the resonances in these waves. The observed phase variation for the \sdash, \pdash and \dwave s do not match existing measurements of $I=\half$ $\Km\pip$ scattering in the invariant mass range in which scattering is predominantly elastic. If the data are mostly $I=\half$, this observation indicates that the Watson theorem, which requires these phases to have the same dependence on invariant mass, may not apply to these decays without allowing for some interaction with the other pion. The production rate of $\Km\pip$ from these decays, if assumed to be predominantly $I=\half$, is also found to have a significant dependence on invariant mass in the region above 1.25 \GeVcc. These measurements can provide a relatively model-free basis for future attempts to determine which strange scalar amplitudes contribute to the decays.