Normalization of partial wave CP asymmetries in three-body decays of heavy hadrons

TL;DR

This paper introduces a novel normalization method for Partial-Wave CP Asymmetries in heavy hadron decays, enabling more accurate interference analysis and avoiding misleading results in multi-body decay studies.

Contribution

The paper proposes a new normalization approach for PWCPAs that ensures consistent statistical errors, improving the reliability of CP violation measurements in heavy hadron decays.

Findings

Quasi-normalized PWCPAs reduce potential distortions in CP asymmetry analysis.

Application to B±→π+π−π± decays demonstrates improved interference pattern analysis.

Method can be applied to other multi-body decay channels for better CP violation studies.

Abstract

CP violation in hadronic multi-body decays has been extensively studied, and the experimental breakthrough in the heayy baryon sector was made recently. Partial-Wave CP Asymmetries (PWCPAs) in multi-body decays of heavy hadrons, which although provide us with more interference information, suffer from the normalization problem, as is pointed out in this paper. We propose a novel solution to this problem. We introduce a set of extra factors to rescale the PWCPAs to the proper sizes. Instead of determining the set of factors according to the normalization requirement, we demand that all the PWCPAs have the same statistical errors. In this way, we obtain a set of quasi-normalized PWCPAs, in the sense that they are close to the ideal normalized ones. As an application, we perform an analysis of PWCPAs in the decay channel $B^\pm\to\pi^+\pi^-\pi^\pm$. We focus on the phase space region where the invariant mass of the $\pi^+\pi^-$ pair varies around the vector resonance $\rho^0(1450)$. Based on the data of the LHCb collaboration, the interference patterns among the resonances $\rho^0(1450)$, $f_2(1270)$, and $f_0(1500)$ and their contributions to the quasi-normalized PWCPAs are analyzed. The analysis indicates that the quasi-normalized PWCPAs can avoid potential misleading or distorted results comparing with some other alternatively defined ones.