Antideuteron production from beauty-hadron decays: a first phenomenological study

Abstract

Light antinuclei, such as antideuteron (d) and antihelium (3He,4He), provide a link between collider physics and indirect Dark Matter searches. Despite extensive studies of antinucleus production in high-energy collisions, d production from beauty-hadron decays remains experimentally unconstrained and has not yet been quantitatively predicted. In this work, we present the first phenomenological study of d production from Λb baryon and B- meson decays, providing the first estimates of the corresponding branching ratios. Beauty-hadron decays are simulated with PYTHIA using realistic input kinematics and three hadronization scenarios. Antideuteron formation is modelled through a quantum-mechanical coalescence approach based on an d wave function derived from the Argonne v18 nucleon-nucleon potential. Depending on the adopted hadronization model, we estimate inclusive branching ratios to be (5.68 0.02)×10-4 < BR(Λb → d+X) < (1.408 0.004)×10-3 and (7.4 0.3)×10-6 < BR(B- → d+X < (4.34 0.07)×10-5. The predicted rapidity- and transverse-momentum-differential yields populate the kinematic region where d can be identified by the ALICE experiment, motivating dedicated searches for these decay channels. These results provide a quantitative benchmark for d production from beauty-hadron decays and establish a phenomenological framework to support future experimental searches, with potential implications beyond collider physics.