Continuous error correction for Ising anyons

Hutter, Adrian; Wootton, James R.

doi:10.1103/physreva.93.042327

Cited by 7 publications

(6 citation statements)

References 53 publications

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“…Specific examples of error correcting schemes for Ising anyons [42], the Φ − Λ model [19] and Fibonacci anyons [43] have been investigated numerically and found to display threshold behaviours. Additionally, greedy hard-decision renormalization group decoders can error-correct any systems giving rise to anyonic excitations [44,45]. However, none of these studies have considered the case where the charge measurements are faulty, a serious complication for all the previous methods.…”

Section: Introductionmentioning

confidence: 99%

Fault-Tolerant Quantum Error Correction for non-Abelian Anyons

Dauphinais

Poulin

2017

Commun. Math. Phys.

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While topological quantum computation is intrinsically fault-tolerant at zero temperature, it loses its topological protection at any finite temperature. We present a scheme to protect the information stored in a system supporting non-cyclic anyons against thermal and measurement errors. The correction procedure builds on the work of Gács [1] and Harrington [2] and operates as a local cellular automaton. In contrast to previously studied schemes, our scheme is valid for both abelian and non-abelian anyons and accounts for measurement errors. We analytically prove the existence of a fault-tolerant threshold for a certain class of non-Abelian anyon models, and numerically simulate the procedure for the specific example of Ising anyons. The result of our simulations are consistent with a threshold between 10 −4 and 10 −3 .

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Section: Introductionmentioning

confidence: 99%

Fault-Tolerant Quantum Error Correction for non-Abelian Anyons

Dauphinais

Poulin

2017

Commun. Math. Phys.

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“…In practice, quasiparticle poisoning may also arise from the electrical driving of skyrmions. However, similar issues occur for the manipulation of MBSs in quantum wires as well [34][35][36], and in principle a continuous error correction is necessary for performing TQC [37]. References [38][39][40] discussed general approaches to optimization of TQC in the presence of quasiparticle poisoning.…”

Section: Quasiparticle Spectrummentioning

confidence: 99%

Majorana bound states in magnetic skyrmions

et al. 2016

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Magnetic skyrmions are highly mobile nanoscale topological spin textures. We show, both analytically and numerically, that a magnetic skyrmion of an even azimuthal winding number placed in proximity to an s-wave superconductor hosts a zero-energy Majorana bound state in its core, when the exchange coupling between the itinerant electrons and the skyrmion is strong. This Majorana bound state is stabilized by the presence of a spin-orbit interaction. We propose the use of a superconducting trijunction to realize non-Abelian statistics of such Majorana bound states.

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“…Recent investigations have begun to explore quantum error correction for nonabelian anyon models [25][26][27][28][29]. Nonabelian anyon models are especially interesting because braiding and fusion of these anyons in general allows for the implementation of universal quantum computation.…”

mentioning

confidence: 99%

“…Nonabelian anyon models are especially interesting because braiding and fusion of these anyons in general allows for the implementation of universal quantum computation. However, the initial studies of error-correction in nonabelian anyon systems have focused on specific models, such as the Ising anyons [25,29] and the so-called Φ-Λ model [26,27] that, while nonabelian, are not universal for quantum computation. The general dynamics of these particular anyon models is known to be efficiently classically simulable, a fact that was exploited to enable efficient simulation of error correction in these systems.…”

mentioning

confidence: 99%

Classical simulation of quantum error correction in a Fibonacci anyon code

2017

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Classically simulating the dynamics of anyonic excitations in two-dimensional quantum systems is likely intractable in general because such dynamics are sufficient to implement universal quantum computation. However, processes of interest for the study of quantum error correction in anyon systems are typically drawn from a restricted class that displays significant structure over a wide range of system parameters. We exploit this structure to classically simulate, and thereby demonstrate the success of, an error-correction protocol for a quantum memory based on the universal Fibonacci anyon model. We numerically simulate a phenomenological model of the system and noise processes on lattice sizes of up to 128 × 128 sites, and find a lower bound on the errorcorrection threshold of approximately 0.125 errors per edge, which is comparable to those previously known for abelian and (non-universal) nonabelian anyon models.

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Continuous error correction for Ising anyons

Cited by 7 publications

References 53 publications

Fault-Tolerant Quantum Error Correction for non-Abelian Anyons

Fault-Tolerant Quantum Error Correction for non-Abelian Anyons

Majorana bound states in magnetic skyrmions

Classical simulation of quantum error correction in a Fibonacci anyon code

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