Strongest nonlocal sets with minimum cardinality in multipartite systems

Abstract

Quantum nonlocality based on state discrimination describes the global property of the set of orthogonal states and has a wide range of applications in quantum cryptographic protocols. Strongest nonlocality is the strongest form of quantum nonlocality recently presented in multipartite quantum systems: a set of orthogonal multipartite quantum states is strongest nonlocal if the only orthogonality-preserving local measurements on the subsystems in every bipartition are trivial. In this work, we found a construction of strongest nonlocal sets in Cd1 Cd2 Cd3 (2≤ d1≤ d2≤ d3) of size d2d3+1 without stopper states. Then we obtain the strongest nonlocal sets in four-partite systems with d3+1 orthogonal states in Cd Cd Cd Cd (d≥2) and d2d3d4+1 orthogonal states in Cd1 Cd2 Cd3 Cd4 (2≤ d1≤ d2≤ d3≤ d4). Surprisingly, the number of the elements in all above constructions perfectly reaches the recent conjectured lower bound and reduces the size of the strongest nonlocal set in Cd Cd Cd Cd of [https://doi.org/10.1103/PhysRevA.108.062407Phys. Rev. A 108, 062407 (2023)] by d-2. In particular, the general optimal construction of the strongest nonlocal set in four-partite system is completely solved for the first time, which further highlights the theory of quantum nonlocality from the perspective of state discrimination.