Constraints on long-lived di-baryons and di-baryonic dark matter

Abstract

A color-flavor-spin singlet state of six quarks uuddss (S, or sexaquark) has been argued to be a potentially undiscovered deeply bound, long-lived hadron. Theoretical calculations of the S mass have been made in the literature, widely varying from deeply-bound 1.2 GeV to weakly-bound 2.2 GeV. Given the spread of the mass predictions, it is vital to derive observational constraints on the state as a function of the mass. The transition rates between S and two baryons are governed by g, the effective Yukawa coupling between S and two baryons with the same quantum numbers as S. In this paper, we place strong observational constraints on g, improving on various previous limits; additional limits assuming S is dark matter are also presented.