Deciphering Hypertriton and Antihypertriton Spins from Their Global Polarizations in Heavy-Ion Collisions

TL;DR

This paper proposes a new method to determine the spin and internal structure of hypertriton and antihypertriton hypernuclei by analyzing their global polarization in heavy-ion collisions, which could clarify their production mechanisms.

Contribution

The study introduces a novel approach using hypertriton global polarization dependence on beam energy to decipher its total and internal spin structure, advancing hypernuclear physics.

Findings

Distinct beam energy dependence of polarization for different spin structures.

Potential to determine hypertriton spin and internal configuration.

Provides insights into hypernuclei production mechanisms in heavy-ion collisions.

Abstract

Understanding the properties of hypernuclei is crucial for constraining the nature of hyperon-nucleon ($Y\text{-}N$) interactions, which plays a key role in determining the inner structure of compact stars. The lightest hypernuclei and antihypernuclei are the hypertriton ($^3_\Lambda\text{H}$), which consists of a pair of nucleons and a $\Lambda$ hyperon, and its antinucleus (${^3_{\bar{\Lambda}}}\overline{\rm H}$). Significant knowledge has recently been acquired regarding the mass, lifetime, and binding energy of $^3_\Lambda\text{H}$. However, its exact spin, whether $\frac{1}{2}$ or $\frac{3}{2}$, remains undetermined in both experimental and theoretical studies. Here, we present a novel method of using the hypertriton global polarization in heavy-ion collisions to decipher not only its total spin but also its internal spin structure. This method is based on the finding that its three different spin structures exhibit distinct beam energy dependence of its global polarization when it is produced in these collisions from the coalescence of proton, neutron and $\Lambda$. Future observations of the hypertriton and antihypertriton global polarizations thus provide the opportunity to unveil the spin structures of hypertriton and antihypertriton and their production mechanisms in heavy-ion collisions.