Enhancing the sensitivity to neutrino oscillation parameters using synergy between T2K, NOνA and JUNO

Abstract

We study the impact of combining the present NOνA and T2K data with simulated data from the JUNO experiment on the determination of the leptonic CP phase and the neutrino mass hierarchy. The current NOνA data exhibit a hierarchy--δ CP degeneracy, admitting both normal hierarchy (NH) with δ CP ∈ [0,180], and inverted hierarchy (IH) with δ CP ∈ [180,360] solutions at comparable significance, while T2K prefers δ CP 270 for both hierarchies, leading to a 2σ tension between the two experiments for normal hierarchy. Using detailed GLoBES simulations, we show that future JUNO data with excellent hierarchy sensitivity, can lift the hierarchy--δ CP degeneracy in NOνA and strengthen the hierarchy reach of T2K in spite of having no δ CP sensitivity. Allowing the hierarchy to be a free parameter in the fit, if the true ordering is IH, JUNO aligns the NOνA and T2K allowed regions and resolves their present tension; if NH is true, the tension continues to persist. We also show that JUNO's precise measurement of |Δ31| leads to improved constraints on 2θ23 and δ CP for normal mass hierarchy in NOνA even though JUNO itself is insensitive to these parameters. Finally, updated solar parameter measurements from JUNO's first data release further enhance the combined precision. Our results demonstrate that JUNO plays a crucial synergistic role in the global neutrino oscillation programme, enabling a more robust determination of the mass ordering and improving the sensitivity to the CP phase when combined with long-baseline data.