New physics in s d semileptonic transitions: rare hyperon vs. kaon decays
Abstract
We investigate the potential of rare hyperon decays to probe the short distance structure in the s d and s d+- transitions. Hyperon decays into neutrinos (B1 B2) can be reliably predicted by using form factors determined in baryon chiral perturbation theory. Their decay rates are sensitive to different short-distance operators, as compared to their kaon counterparts, and the corresponding branching fractions are in the range of 10-1410-13 in the standard model. In the context of the low-energy effective theory, we find that the anticipated BESIII measurements of the B1 B2 decays would lead to constraints on new physics in the purely axial vector d γμγ5 s current that are stronger than the present limits from their kaon siblings K ππ. On the other hand, although hyperon decays into charged leptons are dominated by long-distance hadronic contributions, angular observable such as the leptonic forward-backward asymmetry is sensitive to the interference between long- and short-distance contributions. We discuss the sensitivity to new physics of a potential measurement of this observable in comparison with observables in the kaon decays KLμ+μ- and K+π+μ+μ-. We conclude that the current kaon bounds are a few orders of magnitude better than those that could be obtained from + pμ+μ- except for two scenarios with new physics in the ( d γμ s)(γμγ5) and ( d γμ γ5s)(γμ) currents. Finally, we point out that the loop effects from renormalization group evolution are important in this context, when relating the low-energy effective field theory to new physics models in the UV.
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