Collective Operations Can Exponentially Enhance Quantum State Verification

Maximally entangled states are a key resource in many quantum communication and computation tasks, and their certification is a crucial element to guarantee the desired functionality. We introduce collective strategies for the efficient, local verification of ensembles of Bell pairs that make use of an initial information and noise transfer to few copies prior to their measurement. In this way the number of entangled pairs that need to be measured and hence destroyed is significantly reduced as compared to previous, even optimal, approaches that operate on individual copies. Moreover, the remaining states are directly certified. We show that our tools can be extended to other problems and larger classes of multipartite states.

Automated summary

This study introduces collective strategies for the efficient, local verification of ensembles of Bell pairs, reducing the number of entangled pairs that need to be measured and destroyed by utilizing initial information and noise transfer. The remaining states can be directly certified.