Observation of quantum entanglement in pair production via electron-positron annihilation

Abstract

We report the observation of quantum entanglement in pairs produced via electron-positron annihilation, specifically through the decay J/ . By analyzing the angular correlations of the subsequent weak decays pπ- and pπ+, we derive normalized observables Oi~(i=0,1,…,4) that distinguish entangled states from separable ones. Theoretical predictions for these observables are established, with violations of separable-state bounds serving as unambiguous signatures of entanglement. Experimental measurements at θ = 0 yield O1minObserved = -0.7374 0.0011 0.0016, significantly exceeding the classical limit of -0.5 with a statistical significance of 124.9σ. For |θ|<0.4883, the observed O1Observed consistently exhibits O1Observed < -12 with a statistical significance of at least 5σ. Since 69.3\% of the decay events involving p+π- and p+π+ are spacelike-separated, our results confirming the persistence of quantum entanglement in the system provide strong support for the non-locality of quantum mechanics. The findings are consistent with theoretical expectations under decoherence-free conditions, highlighting the potential of hyperon pairs as probes for fundamental quantum phenomena.