Abstract
The two kaon factories, KOTO and NA62, are at the cutting edge of the intensity frontier, with an unprecedented numbers of long lived and charged Kaons, ~ 10^{13}, being measured and analyzed. These experiments have currently a unique opportunity to search for dark sectors. In this paper, we demonstrate that searches done at KOTO and NA62 are complementary, both probing uncharted territories. We consider two qualitatively different physics cases. In the first, we analyze models of axion-like-particles (ALP) which couple to gluons or electroweak gauge bosons. In the second, we introduce a model based on an approximate strange flavor symmetry that leads to a strong violation of the Grossman-Nir bound. For the first scenario, we design a new search strategy for the KOTO experiment, K_L -> pi^0 a -> 4 gamma . Its expected sensitivity on the branching ratio is at the level of 10^{-9}. This demonstrates the great potential of KOTO as a discovery machine. In addition, we revisit other bounds on ALPs from Kaon factories, highlighting the main sources of theoretical uncertainty, and collider experiments, and show new projections. For the second scenario, we show that the model may be compatible with the preliminary analysis of the KOTO-data that shows a hint for New Physics.
Original language | English |
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Article number | 110 |
Number of pages | 47 |
Journal | Journal of High Energy Physics |
Volume | 2020 |
Issue number | 8 |
Early online date | 24 Aug 2020 |
DOIs | |
Publication status | Published Online - 24 Aug 2020 |
Funding
We thank Wolfgang Altmannshofer, Gaia Lanfranchi, and Hajime Nanjo for the useful discussion. The research of SG is supported in part by the NSF CAREER grant PHY-1915852. SG would like to thank the Aspen Center for Physics under NSF grant PHY-1607611, where part of this work was performed. The work of GP is supported by grants from The U.S.- Israel Binational Science Foundation (BSF), European Research Council (ERC), Israel Science Foundation (ISF), Yeda-Sela-SABRA-WRC, and the Segre Research Award. KT is supported by the US Department of Energy grant DE-SC0010102.