Does the Weinberg angle allow a local hidden-variable description for the leptonic decays of an entangled ZZ pair?

Abstract

Quantum entanglement in di-boson systems offers a useful testing ground for exploring the boundary between quantum-mechanical correlations and classical descriptions based on local hidden variables. In this work, I study the spin-polarization state of a Z1Z2 pair produced from the decay of a spin-0 particle and investigate whether the angular correlations predicted by quantum field theory (QFT) in the leptonic decays Z1( e-1 e+1)Z2( e-2 e+2) can be reproduced by a local hidden-variable theory (LHVT) under angular-momentum conservation. By matching the LHVT angular distribution to the QFT prediction coefficient by coefficient, I derive the conditions under which an LHVT construction exists. For the case w≠ 0, I show that, apart from trivial product-state configurations, an LHVT construction exists only for a unique entangled state, corresponding to a1=a3=-a2=1/3 and b2=b3=0, together with restricted windows of the weak-mixing angle θW. For w=0, I derive a necessary and sufficient criterion for the existence of an LHVT construction in terms of a closed set of algebraic and positivity conditions. As an application, I consider the phenomenologically relevant interaction sZμZμ and show that an LHVT construction exists at threshold ms=2mZ, whereas it does not exist for ms>2mZ.