Abstract
Quantum entanglement is a key resource for foundational quantum information and communication tasks, such as teleportation, entanglement swapping and quantum key distribution [1]. Quantum steering is a quantum correlation that is distinct from other nonclassical correlations such as Bell nonlocality [2] and entanglement. Steering describes the effect of measuring one system, let’s say Alice, and affecting the measurement results on the other system, let’s say Bob. Moving through the hierarchy of nonlocal classes, from Bell nonlocality towards nonseparability, requires an increasing number of parties and apparatus that need to be trusted but gives access to protocols which are more robust to noise for projective measurements [3,4]. In a quantum steering task [5] the correlations of Alice and Bob’s measurement outcomes are tested against a classical probability bound which can be only violated if the state shared between the parties is quantum steerable.
© 2019 IEEE
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