Hybrid ion-ensemble nodes match bandwidths to enable parallel probabilistic entanglement generation, yielding a conceptual speed-up for ion-ion entanglement over hundreds of kilometers.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
fields
quant-ph 3verdicts
UNVERDICTED 3representative citing papers
QRQT protects quantum teleportation's classical channel with PQC, showing quantum memory coherence as the central bottleneck that caps secure distance at 191-199 km and produces a non-monotonic joint attack probability.
The work extends a prior protocol to compare single-click and double-click entanglement generation between ions over hundreds of kilometers, showing that optimal choice depends on phase stability and interface efficiencies.
citing papers explorer
-
Hybrid Single-Ion Atomic-Ensemble Node for High-Rate Remote Entanglement Generation
Hybrid ion-ensemble nodes match bandwidths to enable parallel probabilistic entanglement generation, yielding a conceptual speed-up for ion-ion entanglement over hundreds of kilometers.
-
Quantum-Resistant Quantum Teleportation
QRQT protects quantum teleportation's classical channel with PQC, showing quantum memory coherence as the central bottleneck that caps secure distance at 191-199 km and produces a non-monotonic joint attack probability.
-
Single and Double-click High-Rate Entanglement Generation Between Distant Ions Using Multiplexed Atomic Ensembles
The work extends a prior protocol to compare single-click and double-click entanglement generation between ions over hundreds of kilometers, showing that optimal choice depends on phase stability and interface efficiencies.