Certified Randomness From Steering Using Sequential Measurements

Abstract: The generation of certifiable randomness is one of the most promising applications of quantum technologies. Furthermore, the intrinsic non-locality of quantum correlations allow us to certify randomness in a device-independent way, i.e., we do not need to make assumptions about the devices used. Due to the work of Curchod et al. a single entangled two-qubit pure state can be used to produce arbitrary amounts of certified randomness. However, the obtaining of this randomness is experimentally challenging as it … Show more

“…For Alice1, Bob1 adopt the same measurement strength, we observed double EPR steering simultaneously while it is shown that double Bell-CHSH inequality violations cannot be obtained. The results present here not only shed new light on the understanding of interplay between quantum measurement and non-locality, but also may have important applications such as unbounded randomness certification [11,[30][31][32], randomness access code [33,34] and one-sided device independent quantum key distribution [35][36][37][38].…”

Einstein-Podolsky-Rosen Steering in Two-sided Sequential Measurements with One Entangled Pair

“…For Alice1, Bob1 adopt the same measurement strength, we observed double EPR steering simultaneously while it is shown that double Bell-CHSH inequality violations cannot be obtained. The results present here not only shed new light on the understanding of interplay between quantum measurement and non-locality, but also may have important applications such as unbounded randomness certification [11,[30][31][32], randomness access code [33,34] and one-sided device independent quantum key distribution [35][36][37][38].…”

Einstein-Podolsky-Rosen Steering in Two-sided Sequential Measurements with One Entangled Pair

Einstein-Podolsky-Rosen steering in two-sided sequential measurements with one entangled pair

Sharing quantum steering via standard projective measurements