Quantum computing with multidimensional continuous-variable cluster states in a scalable photonic platform
Bo-Han Wu, Rafael N. Alexander, Shuai Liu, Zheshen Zhang
Abstract
This paper investigates a scalable architecture for photonic one way quantum computing using large scale entangled states. The proposed architecture utilizes frequency and time multiplexing in an integrated quantum photonic platform to generate three dimensional continuous variable cluster states and to realize quantum logic gates, two key ingredients for fault-tolerant quantum computing.
Topics & Concepts
PhotonicsCluster stateQuantum computerScalabilityComputer scienceQuantumQuantum networkMultiplexingCluster (spacecraft)Quantum sensorQuantum entanglementKey (lock)Electronic engineeringQuantum technologyOne-way quantum computerPhysicsComputational scienceTopology (electrical circuits)Quantum imagingScale (ratio)Quantum key distributionQuantum informationQuantum information scienceQuantum error correctionQuantum opticsArchitectureQuantum gateQuantum stateTheoretical computer scienceState (computer science)Quantum teleportationCoherence (philosophical gambling strategy)Quantum channelDistributed computingQuantum algorithmNeural Networks and Reservoir ComputingMechanical and Optical ResonatorsCold Atom Physics and Bose-Einstein Condensates