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Measurement-free fault-tolerant logical-zero-state encoding of the distance-three nine-qubit surface code in a one-dimensional qubit array

Hayato Goto, Yinghao Ho, Taro Kanao

2023Physical Review Research12 citationsDOIOpen Access PDF

Abstract

Generation of logical zero states encoded with a quantum error-correcting code is the first step for fault-tolerant quantum computation but requires considerably large resource overheads in general. To reduce such overheads, we propose an efficient encoding method for the distance-three, nine-qubit surface code and show its fault tolerance. This method needs no measurement, unlike other fault-tolerant encoding methods. Moreover, this is applicable to a one-dimensional qubit array. Observing these facts, we experimentally demonstrate the logical-zero-state encoding of the surface code using a superconducting quantum computer on the cloud. We also experimentally demonstrate the suppression of fast dephasing due to intrinsic residual interactions in this machine by a dynamical decoupling technique dedicated to the qubit array. To extend this method to larger codes, we also investigate the concatenation of the surface code with itself, resulting in a distance-nine, 81-qubit code. We numerically show that fault-tolerant encoding of this large code can be achieved by appropriate error detection.

Topics & Concepts

QubitComputer scienceConcatenation (mathematics)Quantum computerAlgorithmEncoding (memory)Error detection and correctionFault toleranceTopology (electrical circuits)PhysicsQuantumQuantum mechanicsMathematicsArithmeticDistributed computingCombinatoricsArtificial intelligenceQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena