Develops quantum steganography protocols for combinations of classical, entanglement, and quantum communication as covers and cyphers, with improvements relaxing shared-key requirements under milder assumptions.
Continuous variable quantum information: Gaussian states and beyond,
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In finite-depth random linear optical circuits, entanglement grows at most diffusively and robust circuit complexity scales similarly, with depth bounds ensuring near-maximal subsystem entanglement and closeness to Haar unitaries.
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Steganography Protocols for Quantum Channels
Develops quantum steganography protocols for combinations of classical, entanglement, and quantum communication as covers and cyphers, with improvements relaxing shared-key requirements under milder assumptions.
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Entanglement and circuit complexity in finite-depth random linear optical networks
In finite-depth random linear optical circuits, entanglement grows at most diffusively and robust circuit complexity scales similarly, with depth bounds ensuring near-maximal subsystem entanglement and closeness to Haar unitaries.