Single- and Double-Λ Hypernuclear Correlations Calibrate ΛΛ Interaction Energies

Abstract

Double-Λ hypernuclei are essential for probing the ΛΛ interaction in the double-strangeness S=-2 sector, yet the scarcity of experimental data severely limits systematic predictions. We present an evaluation framework based on nuclear many-body theory that exploits the intrinsic structural similarity between single-Λ and double-Λ systems to transfer empirical constraints from the well-mapped S = -1 sector to the S = -2 sector. By analyzing theoretical deviations of binding energies in light single- and double-Λ hypernuclei, we identify a robust linear correlation between two sectors. This correlation enables a statistical evaluation of double-Λ separation energies (BΛΛ) and ΛΛ interaction energies (ΔBΛΛ) for heavier double-Λ hypernuclei, by drawing on a wealth of empirical data from the single-Λ sector with quantified uncertainties. Our results show that evaluated ΔBΛΛ values, while consistent with existing data, are systematically larger than direct relativistic density functional predictions constrained only by the NAGARA event. This discrepancy suggests that standard mean-field-based extrapolations may underestimate ΛΛ correlations and other many-body effects, motivating an evaluation-based correction that offers crucial benchmarks for future S = -2 experiments at facilities such as HIAF and J-PARC.