If the transmissivity of an optical fibre falls below a critical value, its use as a reliable quantum channel is known to be drastically compromised. However, if the memoryless assumption does not hold - e.g. when input signals are separated by a sufficiently short time interval - the validity of this limitation is put into question. In this work we introduce a model of optical fibre that can describe memory effects for long transmission lines. We then solve its quantum capacity, two-way quantum capacity, and secret-key capacity exactly. By doing so, we show that - due to the memory cross-talk between the transmitted signals - reliable quantum communication is attainable even for highly noisy regimes where it was previously considered impossible.
Optical Fibers with Memory Effects and Their Quantum Communication Capacities
Mele F. A.;Giovannetti V.;Lami L.
2024
Abstract
If the transmissivity of an optical fibre falls below a critical value, its use as a reliable quantum channel is known to be drastically compromised. However, if the memoryless assumption does not hold - e.g. when input signals are separated by a sufficiently short time interval - the validity of this limitation is put into question. In this work we introduce a model of optical fibre that can describe memory effects for long transmission lines. We then solve its quantum capacity, two-way quantum capacity, and secret-key capacity exactly. By doing so, we show that - due to the memory cross-talk between the transmitted signals - reliable quantum communication is attainable even for highly noisy regimes where it was previously considered impossible.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
