Litcius/Paper detail

Enhanced energy-constrained quantum communication over bosonic Gaussian channels

Kyungjoo Noh, Stefano Pirandola, Liang Jiang

2020Nature Communications27 citationsDOIOpen Access PDF

Abstract

Quantum communication is an important branch of quantum information science, promising unconditional security to classical communication and providing the building block of a future large-scale quantum network. Noise in realistic quantum communication channels imposes fundamental limits on the communication rates of various quantum communication tasks. It is therefore crucial to identify or bound the quantum capacities of a quantum channel. Here, we consider Gaussian channels that model energy loss and thermal noise errors in realistic optical and microwave communication channels and study their various quantum capacities in the energy-constrained scenario. We provide improved lower bounds to various energy-constrained quantum capacities of these fundamental channels and show that higher communication rates can be attained than previously believed. Specifically, we show that one can boost the transmission rates of quantum information and private classical information by using a correlated multi-mode thermal state instead of the single-mode thermal state of the same energy.

Topics & Concepts

Quantum information scienceQuantum capacityPhysicsQuantum channelQuantum networkQuantum informationClassical capacityQuantumQuantum mechanicsAmplitude damping channelStatistical physicsQuantum noiseComputer scienceTransmission (telecommunications)Quantum sensorQuantum stateNoise (video)Quantum error correctionUpper and lower boundsQuantum operationOpen quantum systemQuantum technologyTopology (electrical circuits)Coherent informationQuantum algorithmQuantum teleportationGaussianQuantum discordQuantum imagingEnergy (signal processing)Quantum limitQuantum Information and CryptographyMolecular Communication and NanonetworksQuantum Computing Algorithms and Architecture