English

Three Exceptions to the Grossman-Nir Bound

High Energy Physics - Phenomenology 2020-08-26 v3

Abstract

We show that the Grossman-Nir (GN) bound, Br(KLπ0ννˉ)4.3Br(K+π+ννˉ)\text{Br}(K_L\to \pi^0\nu \bar\nu)\leq 4.3 \, \text{Br}(K^+\to \pi^+\nu \bar\nu), can be violated in the presence of light new physics with flavor violating couplings. We construct three sample models in which the GN bound can be violated by orders of magnitude, while satisfying all other experimental bounds. In the three models the enhanced branching ratio Br(KLπ0+inv)\text{Br}(K_L\to \pi^0+{\rm inv}) is due to KLπ0ϕ1K_L\to \pi^0\phi_1, KLπ0ϕ1ϕ1K_L\to \pi^0\phi_1\phi_1, KLπ0ψ1ψˉ1K_L\to \pi^0\psi_1\bar \psi_1 transitions, respectively, where ϕ1(ψ1)\phi_1 (\psi_1) is a light scalar (fermion) that escapes the detector. In the three models Br(K+π++inv)\text{Br}(K^+\to \pi^++{\rm inv}) remains very close to the SM value, while Br(KLπ0+inv)\text{Br}(K_L\to \pi^0+{\rm inv}) can saturate the present KOTO bound. Besides invisible particles in the final state (which may account for dark matter) the models require additional light mediators around the GeV-scale.

Cite

@article{arxiv.2005.00451,
  title  = {Three Exceptions to the Grossman-Nir Bound},
  author = {Robert Ziegler and Jure Zupan and Roman Zwicky},
  journal= {arXiv preprint arXiv:2005.00451},
  year   = {2020}
}

Comments

36 pages, 20 figures, v3 version accepted in JHEP with eps'/eps discussion

R2 v1 2026-06-23T15:14:39.109Z