Abstract
We present the results of the first lattice QCD calculation of the $K \to \pi$ matrix elements of the chromomagnetic operator $O_{CM} = g\, \bar s\, \sigma_{\mu\nu} G_{\mu\nu} d$, which appears in the effective Hamiltonian describing $\Delta S = 1$ transitions in and beyond the Standard Model. Having dimension 5, the chromomagnetic operator is characterized by a rich pattern of mixing with operators of equal and lower dimensionality. The multiplicative renormalization factor as well as the mixing coefficients with the operators of equal dimension have been computed at one loop in perturbation theory. The power divergent coefficients controlling the mixing with operators of lower dimension have been determined non-perturbatively, by imposing suitable subtraction conditions. The numerical simulations have been carried out using the gauge field configurations produced by the European Twisted Mass Collaboration with $N_f = 2+1+1$ dynamical quarks at three values of the lattice spacing. Our result for the B-parameter of the chromomagnetic operator at the physical pion and kaon point is $B_{CMO}^{K \pi} = 0.273 ~ (70)$, while in the SU(3) chiral limit we obtain $B_{CMO} = 0.072 ~ (22)$. Our findings are significantly smaller than the model-dependent estimate $B_{CMO} \sim 1 - 4$, currently used in phenomenological analyses, and improve the uncertainty on this important phenomenological quantity.
Highlights
At low energy with respect to the electroweak scale, the standard model (SM) and its possible new physics (NP) extensions are described by an effective Hamiltonian in which the contribution of operators of dimension d 1⁄4 4 þ n are suppressed by n powers of the high-energy scale
We present the results of the first lattice QCD calculation of the K → π matrix elements of the chromomagnetic operator OCM 1⁄4 gsσμνGμνd, which appears in the effective Hamiltonian describing ΔS 1⁄4 1 transitions in and beyond the standard model
The chromomagnetic operator is characterized by a rich pattern of mixing with operators of equal and lower dimensionality
Summary
At low energy with respect to the electroweak scale, the standard model (SM) and its possible new physics (NP) extensions are described by an effective Hamiltonian in which the contribution of operators of dimension d 1⁄4 4 þ n are suppressed by n powers of the high-energy (i.e. the electroweak or NP) scale. It is worth noting that the chirality flipping factor ms=MW, which appears in the Wilson coefficients of the magnetic operators in the SM, is of the same size as ΛQCD=MW, which represents the additional suppression factor of the coefficients of dimension-six operators in the effective Hamiltonian. The relevant matrix elements with an initial kaon involve one, two or three pions in the final states and are of great phenomenological interest for various processes: the long distance contribution to K0 − K 0 mixing [5], ΔI 1⁄4 1=2, K → ππ transitions and ε0=ε [1], CP violation in K → 3π decays [6].
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