Hyperon-pair spin tomography beyond scalar spin correlations

Abstract

Spin correlations measured after hadronization probe how quantum information is transported through confinement. We formulate a process-independent spin-tomography framework for ΛΛ pairs in which the weak-decay angles determine the full two-spin tensor rather than only its scalar trace. Applied to the short-range STAR correlation in unpolarized ppΛΛX, the framework shows that the published scalar PΛΛ leaves a continuous density-matrix degeneracy: separable tensor completions and completions that violate the positive-partial-transpose (PPT) criterion can have the same trace. The missing observables are the transverse and longitudinal tensor components and their anisotropy AC=C-C. A local 3P0 string-breaking benchmark turns the STAR trace into the falsifiable pattern C>0, C<0, and AC>0. We further show that feed-down must be treated as a tensor response rather than as a universal scalar dilution. In the complementary e+e- calibration channel, the same benchmark predicts a centrally enhanced AC of order 0.3 in Belle II kinematics, measurable with about 104 selected pairs for nominal spin-transfer parameters. A claim of entanglement requires the reconstructed two-spin density matrix, not the scalar trace alone, to violate the PPT bound.