Long-distance contributions to flavour-changing processes

TL;DR

This paper discusses recent developments in lattice QCD calculations of long-distance, non-local contributions to flavour-changing processes, including kaon mixing, rare decays, and electromagnetic effects, with a focus on handling infrared divergences.

Contribution

It introduces new methods for computing non-local, long-distance effects in flavour physics on the lattice, including electromagnetic corrections with infrared divergence control.

Findings

Progress in lattice calculations of $K_L$-$K_S$ mass difference

Initial results on rare kaon decay amplitudes

Proposed procedures for infrared divergence cancellation

Abstract

Standard lattice calculations in flavour physics or in studies of hadronic structure are based on the evaluation of matrix elements of local composite operators between hadronic states or the vacuum. In this talk I discuss developments aimed at the computation of long-distance, and hence non-local, contributions to such processes. In particular, I consider the calculation of the $K_L$-$K_S$ mass difference $\Delta m_K=m_{K_L}-m_{K_S}$ and the amplitude for the rare-kaon decay processes $K\to\pi\ell^+\ell^-$, where the lepton $\ell=e$ or $\mu$. Lattice calculations of the long-distance contributions to the indirect $CP$-violating parameter $\epsilon_K$ and to the rare decays $K\to\pi\nu\bar\nu$ are also beginning. Finally I discuss the possibility of including $O(\alpha)$ electromagnetic effects in computations of leptonic and semileptonic decay widths, where the novel feature is the presence of infrared divergences. This implies that contributions to the width from processes with a real photon in the final state must be combined with those with a virtual photon in the amplitude so that the infrared divergences cancel by the Bloch-Nordsieck mechanism. I present a proposed procedure for lattice computations of the $O(\alpha)$ contributions with control of the cancellation of the infrared divergences.