Direct CP violation in charmed meson decays within the standard model

TL;DR

This paper investigates direct CP violation in charmed meson decays within the Standard Model, highlighting the role of long-distance penguin effects and predicting measurable CP asymmetries in specific decay channels, consistent with LHCb observations.

Contribution

It introduces a detailed analysis of CP violation in D meson decays using topological and QCD factorization approaches, emphasizing long-distance penguin effects as a key mechanism.

Findings

CP asymmetry difference between D0→K+K− and π+π− is at the per mille level.

Six decay modes predicted to have large CP violation at the per mille level.

LHCb's observed CP asymmetry difference can be explained without new physics.

Abstract

Direct CP violation in two-body $D\to PP$ and $D\to V\!P$ decays is studied within the framework of the topological amplitude approach for tree amplitudes and the QCD factorization approach for penguin amplitudes. It is the interference between tree and long-distance penguin and penguin-exchange amplitudes that pushes CP asymmetry difference between $D^0\to K^+K^-$ and $\pi^+\pi^-$ modes up to the per mille level. Using the same mechanism, we find that CP asymmetry can also occur at the $10^{-3}$ level in many of the $D\to V\!P$ channels or otherwise be negligibly small. There are six golden modes which have sufficiently large branching fractions and direct CP violation at the per mille level. In particular, the direct CP asymmetry difference between $D^0\to K^+K^{*-}$ and $\pi^+\rho^-$ is predicted to be $(-1.61\pm0.33)\times 10^{-3}$, very similar to the counterpart in the $P\!P$ sector. The LHCb's observation of CP asymmetry difference can be explained within the standard model without the need of new physics. The key lies in the long-distance penguin topology (penguin and penguin-exchange) arising from final-state rescattering.